Monitoring using cellular phones

ABSTRACT

Method and arrangement for obtaining information about a person includes providing the person with a portable device, arranging at least one sensor on the portable device, obtaining information about the person carrying the portable device or an environment around the person carrying the portable device using the at least one sensor of the portable device without manual interaction, and transmitting the obtained information from the portable device to a remote facility. The portable device may be a cell phone or PDA. The location of the cell phone or PDA may be provided by the cell phone or PDA or determined from the information at the remote facility from information provided by the cell phone or PDA relating to, for example, reception of signals thereby.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is:

1. a continuation-in-part (CIP) of U.S. patent application Ser. No.10/940,881 filed Sep. 13, 2004, now U.S. Pat. No. 7,663,502, which is:

-   -   A. a CIP of U.S. patent application Ser. No. 10/457,238 filed        Jun. 9, 2003, now U.S. Pat. No. 6,919,803, which claims priority        under 35 U.S.C. §119(e) of U.S. provisional patent application        Ser. No. 60/387,792 filed Jun. 11, 2002, now expired;    -   B. a CIP of U.S. patent application Ser. No. 10/931,288 filed        Aug. 31, 2004, now U.S. Pat. No. 7,164,117;

2. a CIP of U.S. patent application Ser. No. 11/278,979 filed Apr. 7,2006, now U.S. Pat. No. 7,386,372, which is a CIP of U.S. patentapplication Ser. No. 10/931,288 filed Aug. 31, 2004, now U.S. Pat. No.7,164,117;

3. a CIP of U.S. patent application Ser. No. 11/380,574 filed Apr. 27,2006 which is a CIP of U.S. patent application Ser. No. 10/931,288 filedAug. 31, 2004, now U.S. Pat. No. 7,164,117;

4. a CIP of U.S. patent application Ser. No. 11/619,863 filed Jan. 4,2007 which is a CIP of U.S. patent application Ser. No. 10/931,288 filedAug. 31, 2004, now U.S. Pat. No. 7,164,117;

5. a CIP of U.S. patent application Ser. No. 11/755,199 filed May 30,2007 now U.S. Pat. No. 7,911,324;

6. a CIP of U.S. patent application Ser. No. 11/843,932 filed Aug. 23,2007; and

7. a CIP of U.S. patent application Ser. No. 11/865,363 filed Oct. 1,2007, now U.S. Pat. No. 7,819,003.

All of the foregoing patent application and all references, patents andpatent applications that are referred to below are incorporated byreference in their entirety as if they had each been set forth herein infull.

FIELD OF THE INVENTION

The present invention relates generally to methods and systems forobtaining information about people and their surrounding environmentusing cell phones, PDAs or other similar portable devices.

BACKGROUND OF THE INVENTION

Background of the invention is found in U.S. Pat. No. 6,919,803.

Definitions in the Background of the Invention section of any of theabove-mentioned applications are also generally, but not restrictively,applicable herein.

OBJECTS AND SUMMARY OF THE INVENTION

It is an object of the present invention to provide new and improvedsystems for obtaining information about people and their surroundingenvironment using cell phones, PDAs or similar electronic devices.

In order to achieve this object and possibly others, a method forobtaining information about a person in accordance with the inventionincludes providing the person with a portable device, arranging at leastone sensor on the portable device, obtaining information about theperson carrying the portable device or an environment around the personcarrying the portable device using the at least one sensor of theportable device without manual interaction, and transmitting theobtained information from the portable device to a remote facility. Theportable device may be a cell phone or PDA.

The portable device may be provided with a system to obtain DGPS signalswhich are transmitted from the portable device to the remote facility toenable the location of the portable device to be determined from theDGPS signals at the remote facility. Alternatively, the location of theportable device may be provided by the portable device itself, if notdetermined from the information at the remote facility from informationprovided by the portable device, e.g., information relating to receptionof signals by the portable device.

The portable device can monitor received sounds, via one or moremicrophones and analyze the received sounds and transmit a signalindicative of the received sounds to a remote facility. The portabledevice, e.g., a processor therein, may be trained to recognize thesounds of accidents and transmit an accident indication signal to theremote facility only when the sounds of an accident are recognized.

The information obtained by the sensor may be information about anenvironment around the portable device such as information aboutchemicals in the environment around the person carrying the portabledevice when the sensor is a chemical sensor. An energy harvesting systemmay be arranged in connection with the portable device to generateenergy to power the portable device, or various sensors associatedtherewith.

Sensors arranged in association with the portable device may be one ormore of a temperature sensor, radiation sensor, optical sensor, humiditysensor, chemical sensor, biochemical sensor, biological sensor,acceleration sensor, velocity sensors, displacement sensor, locationsensor, vibration sensor, acoustic sensor and pressure sensor.

In one embodiment, the information obtained using the sensors of theportable device is analyzed at the portable device, e.g., by a processortherein, to determine whether the information satisfies a predeterminedcriteria requiring transmission of the information to the remotefacility and the obtained information is transmitted by a communicationsportion of the portable device only when it satisfies one of thepredetermined transmission criteria.

An arrangement for monitoring a person in accordance with the inventionincludes a portable device including at least one sensor and which iscarried by the person. Each sensor is arranged to obtain informationabout the person carrying the portable device or an environment aroundthe person carrying the portable device without manual interaction. Theportable device includes a processor which analyzes the obtainedinformation to determine whether the obtained information requires atransmission to a remote facility and a communications portion arrangedto transmit the obtained information or a signal representative thereofwhen the processor determines that the obtained information requiressuch a transmission. A remote facility receives and reacts to thetransmitted information. The portable device may include a locatingsystem arranged to obtain DGPS signals in which case, the communicationsportion transmits the obtained DGPS signals to the remote facility toenable the location of the portable device to be determined from theDGPS signals at the remote facility.

When a sensor is a microphone arranged to receive sounds when carried bythe person, the processor analyzes the received sounds and transmits asignal indicative of the received sounds to the remote facility. Morespecifically, the processor recognizes the sounds of accidents andtransmits an accident indication signal to the remote facility only whenthe sounds of an accident are recognized. The processor analyzes theobtained information to determine whether the information satisfies apredetermined criteria requiring transmission of the information to theremote facility and the communications portion is arranged to onlytransmit the obtained information when it satisfies one of thepredetermined transmission criteria.

BRIEF DESCRIPTION OF THE DRAWINGS

The following drawings are illustrative of embodiments of the systemdeveloped or adapted using the teachings of at least one of theinventions disclosed herein and are not meant to limit the scope of theinvention as encompassed by the claims.

FIG. 1 illustrates a first embodiment of a cargo space equipped with asystem in accordance with the invention for obtaining information from atagged object in the cargo space.

FIG. 2 illustrates a second embodiment of a cargo space equipped with asystem in accordance with the invention for obtaining information from atagged object in the cargo space.

FIG. 3 illustrates an embodiment of a cargo space with RF windows.

FIG. 4 illustrates an embodiment of a cargo space with an antennamultiplexer arrangement.

FIG. 5 illustrates an embodiment of a cargo space with multiple antennaswhich enable the position of a tag to be determined based on receptionof signals by the antennas.

FIGS. 6 and 7 are block diagrams of an interrogator with a singleantenna which may be used in the invention.

FIG. 8 is a block diagram of an interrogator with multiple antennaswhich may be used in the invention.

FIG. 9 illustrates systems for deriving or harvesting electrical powerfor use in the invention.

FIG. 10 illustrates a method of using triangulation to determine thelocation of a tag within a cargo space in accordance with the invention.

FIG. 11 is a cutaway view of a vehicle showing possible mountinglocations for vehicle interior temperature, humidity, carbon dioxide,carbon monoxide, alcohol or other chemical or physical propertymeasuring sensors.

FIG. 12 is a schematic of a vehicle with several accelerometers and/orgyroscopes at preferred locations in the vehicle.

FIG. 13 illustrates a driver with a timed RFID standing with groceriesby a closed trunk.

FIG. 14 illustrates the driver with the timed RFID 5 seconds after thetrunk has been opened.

FIG. 15 illustrates a trunk opening arrangement for a vehicle inaccordance with the invention.

FIG. 16A is a view of a SAW switch sensor for mounting on or within asurface such as a vehicle armrest.

FIG. 16B is a perspective view of the device of FIG. 16A with theforce-transmitting member rendered transparent.

FIG. 16C is a perspective view of an alternate SAW device for use inFIGS. 16A and 16B showing the use of one of two possible switches, onethat activates the SAW and the other that suppresses the SAW.

FIG. 16D is a schematic of a RFID controlled by a switch.

FIG. 16E is a schematic of a SAW device controlled by a switch.

FIG. 16F is a schematic of a backscatter antenna which is controlled bya switch.

FIG. 16G is a schematic of circuit for a monitoring system in accordancewith the invention which has two switches.

FIG. 16H illustrates one embodiment of a switch whereby activation ofthe switch provides the energy necessary to power an RFID.

FIG. 17 is a top view of a system for obtaining information about avehicle or a component therein, specifically information about thetires, such as pressure and/or temperature thereof.

FIG. 18 is a side view of the vehicle shown in FIG. 17.

FIG. 19 is a schematic of the system shown in FIGS. 17 and 18.

FIG. 20 is a top view of an alternate system for obtaining informationabout the tires of a vehicle.

FIG. 21 is a perspective view showing a shipping container including oneembodiment of the monitoring system in accordance with the presentinvention.

FIG. 22 is a flow chart showing one manner in which a container ismonitored in accordance with the invention.

FIG. 23A is a cross-sectional view of a container showing the use ofRFID technology in a monitoring system and method in accordance with theinvention.

FIG. 23B is a cross-sectional view of a container showing the use ofbarcode technology in a monitoring system and method in accordance withthe invention.

FIG. 23C is a cross-sectional view of a refrigerated container showingthe use of a diagnostic module in a monitoring system and method inaccordance with the invention.

FIG. 24 is a flow chart showing one manner in which multiple assets aremonitored in accordance with the invention.

FIG. 25 is a schematic showing the use of a cell phone or PDA formonitoring a vehicle in accordance with the invention.

FIG. 26 is a schematic view of overall telematics system in accordancewith the invention.

DETAILED DESCRIPTION OF THE INVENTION

Although many of the examples below relate to a cargo space in an asset,the invention is not limited to any particular space in any particularasset and is thus applicable to all types of assets including vehicles,shipping containers and truck trailers and to all spaces or compartmentsof a vehicle including, for example, the passenger compartment and thetrunk of an automobile or truck.

Referring to the accompanying drawings, FIGS. 1-10 illustrate a methodand system for identifying and locating an RFID-tagged article inside acargo space defined by a frame. The RFID tags can be active, passive ora combination of both, or MIR transmitters, or devices providingbackscatter. The system can employ multiple antennas inside a cargospace, truck trailer or other vehicle cargo space as illustrated inFIGS. 1-6. The system is preferably designed for a low power batteryoperation when the cargo space is not tethered to a power source. Someenergy harvesting methods for powering the system are shown in FIG. 9.The system requires little power and has a low duty cycle when notconnected to a power source thus the system will provide RFID tagidentification for many years with internal battery power.

A passive RFID tag can operate at about 915 MHz (ISM band) complyingwith FCC rule 15, for example, or other rules that may apply either inthe US or other countries. The frequency can be any frequency permittedunder these rules.

FIG. 1 illustrates an embodiment of a cargo space with three antennas10, 12, 14 spaced in a triangular fashion and connected to aninterrogator 16 internal to the cargo space with the antennas 10, 12, 14shown in one possible configuration arranged on a common wall of thecargo space. The internal arrangement of the interrogator 16 to thecargo space means that the interrogator is arranged on one or more ofthe walls defining the cargo space, inside or within one or more of thewalls defined the cargo space and/or within the space defined by thewalls of the cargo space. Specifically, for the shipping container shownin FIG. 1 having a pair of opposed side walls, a pair of opposed frontand rear walls, a roof and a floor, the antennas 10, 12, 14 are arrangedin the front wall. This wall may the fixed wall opposite the door of theshipping container. In other embodiments, the antennas 10, 12, 14 arearranged in the other walls of the container.

The interrogator 16 may be arranged within the triangle defined by theantennas 10, 12, 14, for example, at or about the approximate center ofthe triangle. In other embodiments with multiple antennas, theinterrogator may be situated to be equidistant from all of them.Nevertheless, the location of the interrogator relative to the antennasis not critical to the practice of the invention and the interrogatormay be placed anywhere on the asset defining the cargo space, or evenseparate and apart from the asset, as described below. The interrogator16 may be connected to the antennas 10, 12, 14 using wires orwirelessly. The interrogator 16 can be connected to a satellite or othercommunication unit 18 from the interior of the cargo space using a wireor wirelessly using an antenna. As shown, communication unit 18 isarranged on a roof of the asset. The satellite or other communicationunit 18 can have an external antenna and can be used to send taginformation to a remote site. The distances from each antenna 10, 12, 14to an RFID device or tag 20 are shown as D1, D2 and D3. These distancescan be measured by an interrogator 16 shown schematically in FIG. 8, orby a processor associated with or resident within the interrogator 16 orseparate therefrom. The processor could also process the distances toderive other information about the RFID device 20 or an object inconnection with which the RFID device 20 is mounted. For example, such aprocessor can also derive additional or alternative information aboutthe RFID device 20, such as motion thereof or its identification if itis designed to generate a return signal with identification data.

There are known arrangements of or programming for interrogator 16, orthe processor associated therewith, to measure or otherwise determinedistances D1, D2 and D3 based on the return signals. However, in oneparticular embodiment, RFID devices 20 are used which have thecapability of returning a signal at a precise time with this knowledgebeing used to determine the distance between the RFID device or objectin connection therewith and the antennas 10, 12, 14. To achieve this,the interrogator 16 and RFID device 20 are each provided with a clock,and the RFID device 20 synchronizes its clock upon reception of anysignal from any of the antennas 10, 12, 14 relative to theinterrogator's clock returns a signal, if it receives any signal fromany of the antennas 10, 12, 14, only after synchronization of its clockto the interrogator's clock. The interrogator 16, or processorassociated therewith, is arranged or programmed to predict a transmittime at which the RFID device 20 will return a signal after reception ofa signal whose transmission is controlled by the interrogator 16. Theactual arrival time of the return signal from the RFID device 20 isanalyzed relative to the predicted transmit time (the time the returnsignal was transmitted by the RFID device 20), e.g., compared thereto,to enable a measurement of a distance between the RFID device 20 and theantennas 10, 12, 14 to be determined. Thus, in this embodiment, the RFIDdevice 20 returns a signal at a specific time after receipt of aninterrogation signal or pulse from one or more of the antennas 10, 12,14, at a specific time after the signal or pulse was sent by one or moreof the antennas 10, 12, 14 or at an appointed or predesignated time. Inthe latter case, predesignation of times might entail creating aspecific formula for determining the predesignated times.

In one embodiment when the interrogator 16 causes transmission ofsignals from multiple antennas 10, 12, 14, the RFID 20 when receivingsignals from one or more of these antennas 10, 12, 14 may be arranged orprogrammed to provide information in the return signal indicative of aphase or relative time of reception of signals from the multipleantennas. The processor associated with the interrogator 16 wouldanalyze the return signals and from the phase or time receptioninformation, derive information about the RFID device 20 or object towhich it is mounted, such as distance information or motion information.

FIG. 2 illustrates an embodiment of a cargo space with three antennas22, 24, 26 spaced in a triangular fashion located on the roof, ceilingor top of the shipping container defining the cargo space and connectedto an interrogator 28 internal to the cargo space. The interrogator 28is connected to an external antenna 30 and can also be connected to asatellite or other communication unit as in FIG. 1. The distances fromeach antenna 22, 24, 26 to the RFID device or tag 32 are shown as D1, D2and D3. The interrogator 28 may be arranged within the triangle definedby the antennas 22, 24, 26 or elsewhere. The variations described forthe embodiment shown in FIG. 1 are equally applicable to thisembodiment.

Mounting of the antennas 22, 24, 26, or possibly any other type ofelectromagnetic energy transmitter, on the roof of the shippingcontainer is advantageous in that is it very unlikely to interfere withthe maximum use of the cargo space provided by the shipping container.

FIG. 3 illustrates an embodiment of a shipping container defining acargo space with multiple RF windows 34, 36, 38, 40 in the frame of thecontainer. The windows 34, 36, 38, 40 allow for the signal to and fromone or more RFID devices or tags 42 in the cargo space to transmit andreceive signals from an interrogator 44 such as shown schematically inFIG. 6 which can be located outside of the cargo space. This embodimenttherefore enables an interrogator 44 to obtain signals via antenna 46from an RFID device or tag 42 within a cargo space while theinterrogator 44 is separate and apart from the cargo space. Such RFwindows would be needed anytime the frame is interposed between theinterrogator and its antenna, and the space defined by the frame. It isthus conceivable that the interrogator and its antenna may even bearranged on the frame yet require one or more RF windows to enablesignals from the antenna to pass into the space and return signals fromany RFID devices in the space to pass out of the space to be received bythe antenna.

The size, location and number of RF windows in an asset, such as theshipping container defining the cargo space shown in FIG. 3, can varydepending on, for example, the expected and possible locations of RFIDdevices or tags in the cargo space or other space defined by the asset,the dimensions of the cargo space or other space defined by the asset,and the expected relative position between the antenna of theinterrogator and the RFID devices. It is possible that one or more RFwindows be situated at the same location on a particular type ofshipping container and that a scanning system being provided for usewith such shipping containers which is designed to accept one or moreshipping containers in a position in which the RF windows areautomatically properly aligned with an antenna of an interrogator of thescanning system. This will simplify the scanning of the shippingcontainers.

FIG. 4 illustrates an embodiment of a cargo space with a multiple ofinternal antennas 46, 48, 50, 52 connected to an antenna multiplexer 54(such as a PE4261 SP4T RF UltraCMOS™ Flip Chip Switch manufactured byPeregrine Semiconductor). As shown, antennas 46, 48, 50, 52 are allarranged at the top of the shipping container defining the cargo space.

The multiplexer 54 may be connected to an antenna 56 outside of thecargo space (an external antenna, yet one which is still mounted on orattached to the frame defining the cargo space) for communications withan external interrogator such as illustrated in FIG. 6. A transceivermay be connected between the multiplexer 54 and the external antenna 56in order to increase the signal strength of the signals from the RFIDdevice 58 which is internal to the shipping container defining the cargospace. The external antenna 56 is sued to communicate with aninterrogator and its antenna which is used to control the transmissionsof signals by the antennas 46, 48, 50, 52 and process signals receivedby the antennas into information about the RFID device 58 or an objecton or to which the RFID device is mounted or attached. A processor maybe used for this purpose and may either be part of the interrogator orseparate therefrom.

The RFID device location in the cargo space may be determined bymeasuring the distances from the RFID device 58 to each of the internalantennas 46, 48, 50, 52 by triangulation as illustrated in FIG. 10 anddescribed below. Triangulation may be used in the same manner wheneverthere are at least three antennas which receive signals generated by thepresence of an RFID device in a monitored cargo space.

FIG. 5 illustrates an embodiment of a cargo space with multiple internalantennas 60, 62, 64, 66, 68, 70 connected to an antenna multiplexer 72(such as the PE4261). The multiplexer 72 may be connected to an externalantenna 74 outside of the cargo space for communications with anexternal interrogator such as illustrated in FIG. 6. As in theembodiment of FIG. 4, a transceiver may be connected between themultiplexer 72 and the outside antenna 74 for increasing the signalstrength of the signals from the RFID device 76 or RFID devices whichare within the cargo space. The RFID device location in the cargo spacemay be determined by measuring the signal strengths from the internalantennas 60, 62, 64, 66, 68, 70, whereby the antenna closest to the RFIDdevice 76 will have the largest or strongest signal therefore the zonewhere the RFID device 76 is located in the cargo space may bedetermined.

When using multiple antennas on an asset and deriving the generallocation of area of the RFID device or RFID-device equipped object basedon the signal strength, the antennas can be distributed or spaced apartalong any single dimension of the asset, e.g., longitudinally for theshipping container as shown in FIG. 5. In this manner, the approximatelongitudinal location of the RFID device or object equipped therewithcould be determined. Of course, when two antennas provide signals havingequal strength, it could be derived that the RFID device is situatedexactly between the antenna locations.

In one embodiment, the antennas are arranged along a longitudinal centerline of the cargo space, e.g., down the center of a shipping trailer orcontainer.

FIG. 6 illustrates a block diagram of an interrogator with a singleantenna which may be used in the embodiments herein. Information fromthis interrogator may be displayed locally or sent over a communicationslink, such as a satellite, cell phone, internet or equivalent link, to aremote location for processing, logging, re-transmission or for anyother purpose.

The interrogator 78 includes a pair of oscillators 80, 82, a modulator84 processing the output from oscillators 80, 82 and providing output toa power amplifier 86, a circulator 88 connected to the power amplifier86 and providing a signal for transmission by the antenna 90 with asignal being received by antenna 90 being directed through thecirculator 88 to an amplifier 92, and a phase detector 94 connected tothe oscillator 82, modulator 84 and amplifier 92 and performing a phasecomparison between the signals transmitted and received via antenna 90.A microprocessor 96 is coupled to the modulator 84 and phase detector 94and analyzes the phase comparison to determine information about a RFIDdevice which returns a signal to the antenna 90. This information may bedistance or range information, which may be provided to an externaldevice or a display. Additionally or alternatively, if may beidentification information or motion information.

The information may be derived using the known speed of the waves andthe time for travel of the waves, since the distance between the antennaand the RFID-device is equal to one-half the speed multiplied by thetotal travel time. The frequency can be calculated from the determinedtime and the range of the phase detector is radians.

FIG. 7 illustrates a block diagram of an interrogator with a singleantenna similar to that shown in FIG. 6. Information from thisinterrogator may be displayed locally or sent over a communications linkvia a communications device 97 to a remote location as above. Thisembodiment of an interrogator shows a method for measuring the distancefrom the interrogator antenna to the antenna of an RFID device. Themodulation used may be either amplitude or frequency; the phase detectormay be of the phase/frequency type. An exemplifying calculations foramplitude modulation would involve determining the time for travel ofthe waves, which is equal to twice the distance between the antenna andthe RFID-device (having a set maximum of 5 meters) divided by the speedof light. The frequency can be calculated from the determined time andthe range of the phase detector is radians.

FIG. 8 illustrates a block diagram of an interrogator with multipleantennas which may be used in embodiments herein. The block diagram issimilar to that shown in FIG. 6 and the same reference numeralsdesignate the same elements. However, in this embodiment, individualantennas are selected by a MUX 98 (which may be one designated in thefield as a PE4261). The MUX 98 controls the transmission and receptionof signals via antennas 100, 102, 104. Any number of antennas may beprovided, and using the PE4261, up to six antennas may be used. Controlof the MUX 98 may be achieved using the microprocessor 96 which iscoupled thereto.

Information from this interrogator may be displayed locally or sent overa communications link to a remote location as described above. Thisembodiment of an interrogator shows a method for measuring the distancefrom the selected interrogator antenna to a tag antenna. The modulationmay be either amplitude or frequency; the phase detector may be of thephase/frequency type. Example calculations are shown for amplitudemodulation. By using the distances from the antennas 100, 102, 104 to atag, the location of the tag can be calculated by triangulation as shownin FIG. 10 and described below.

FIG. 9 illustrates three exemplary methods for deriving or harvestingelectrical power for the operation of interrogators, multiplexers and/ortransceivers/transmitters, as well as any other electricity consumingdevices on the cargo container needed for the operation or purpose ofgathering information about a tagged object in the cargo space, whethersituated within or in the cargo space or within, in or on the structuredefining the cargo space. These include solar panels 106 (shown in thetop of the cargo container), a vibration to voltage generator 108 (shownon a side of the container) and a magnetic field variation device 110which generates electrical power based on variations in a magnetic fieldcaused by movement of the container.

FIG. 10 illustrates a method of using triangulation to determine thelocation of a typical tag 112 within a cargo space, which may be used inembodiments described herein. The exemplary tag location determinationby triangulation is shown for two dimensions in the x, y plane but maybe readily extended to a three-dimensional x, y, z space.

Let:

R1=The measured range from Antenna 114 to the tag 112.

R2=The measured range from Antenna 116 (a,0) to the tag 112.

a=known distance between antennasR1² :=x ² +y ²y ² :=R1² −x ²  Eq(1)R2²:=(x+a)² +y ²  Eq(2)substituting:R2²:=(x+a)² +R1² −x ²R2² −R1² :=x ²+2a·x+a ² −x ²2·a·x:=R1² −a ²

-   -   R1 and R2 are measured values and a is known by the distance        between the antennas 114, 116 therefore; x can be computed. Once        x is computed y can be found by substituting x into equation 1.

$x:=\frac{( {{R\; 2^{2}} - {R\; 1^{2}} - a^{2}} )}{2 \cdot a}$

The location of the tag 112 in three dimensions can now be easily foundby those skilled in the art.

The above analysis has been based on the time of arrival of a signalfrom a tag at the various antennas. Other methods based on the angle ofarrival can permit vectors to be drawn that pass through the taglocation and then based on the calculation of the intersection of thesevectors, the location of the tag can be found. Information about thistechnique is disclosed, for example, in Z. Wen, L. Li, and P. Wei “FastDirection Using Modified Pseudocovariance Matrix”, IEEE Transactions onAntennas and Propagation, Vol 54, No. 12, December 2006, and articlesreferenced therein.

An alternate approach would be for the antennas to send short pulseswhich all of the tags would hear and record the times of arrival. Thisrecording would then be sent back to the interrogator from which theinterrogator circuitry could determine the location of a tag based onthe pattern of signals that the tag heard. Each antenna could append anID so that the tag could record the tag signal correspondence. Thesetechniques can be based on relative times or on absolute time. Thelatter could be determined by a variety of methods including syncing theclock on each tag with the interrogator clock.

Another method of determining the location of a tag is to enable the tagto either receive or transmit ultrasound. In the latter case, the tagwould emit an ultrasonic pulse when it receives an RF pulse andlisteners distributed around the cargo space would receive eachultrasonic pulse at a different time and thereby know, or enable adetermination of, the distance to the tag. If there are three listeners,then the tag location is known based on the known location of thelisteners.

The methods and systems described above for interacting with RFIDdevices or tags are equally applicable for other types of tags orresponsive devices including but not limited to various SAW devices,resonators and reflectors (e.g., dihedral reflectors), such as disclosedin the applications listed above. The information obtained by themethods and system in accordance with the invention which interact withthese devices may be identification information and/or positionalinformation. In the latter case, when tags are installed onto fixedcomponents of assets, such as a seat or door in a vehicle, theirpresence, positions and/or orientations can be determined and used tocontrol other systems, such as vehicular systems having output whichvarying as a function of the presence, position and/or orientation ofthe components (which may correlate to the presence, position and/ororientation of human occupants of the vehicles).

The methods and system in accordance with the invention can be used tointerrogate multiple RFID devices or similar tags. In this case, theidentification, location and/or motion of multiple RFID devices orobjects associated therewith can be determined.

In a preferred embodiment, the asset is a vehicle and one or morecomponents are equipped with RFID devices. The interrogator controlstransmission of RF signals from the antennas to cause these RFID devicesto generate return signals. Analysis of these return signals by aprocessor associated with the interrogator can be used to deriveinformation about the components. In this regard, reference is made tothe disclosure of U.S. Pat. No. 6,820,897 which is directed to, amongother things, use of resonators arranged on vehicular components.

Additional variations of any of the embodiments of the method and systemdescribed above include the ability of the interrogator or antennamultiplexer to transmit signals from the RFID devices or informationderived from the RFID devices to one or more locations or sites remotefrom the asset containing the RFID device. This allows remote monitoringof assets.

The presence of an interrogator on the same frame or structure whichdefines a space into which RFID devices or objects equipped with RFIDdevices greatly simplifies the ability to scan spaces of these frames orstructures. The objects equipped with the RFID devices may be sensors.In addition, such sensors may be arranged to be independentlyinterrogated by the interrogator which would thus interrogate the RFIDdevices and the sensors. These sensors may be temperature, optical,flow, humidity, chemical, biochemical, current, voltage, magnetic field,electric field, force, acceleration, velocity, displacement, a position,vibration, acoustic, radiation, charge, viscosity, density, electricalresistance, electrical impedance, electrical capacitance, electricalinductance and pressure sensors.

The presence and identification of people can be derived using RFIDdevices, via analysis of information from RFID devices mounted to thevehicle's structure such as seats, and then transmitted off of thevehicle. This concept is disclosed in U.S. Pat. No. 5,829,782, alongwith the presence of tags and tag monitors inside a vehicle.

The methods and systems described above could also be used to determinethe location of RFID devices exterior of a cargo space, yet still withinproximity to, on or in a vehicle containing the interrogator.

The power generated by the antennas may be higher in view of thedirection of the radio frequency signals into a closed cargo space. Inthis regard, transmission rules by the FCC may not apply within anenclosed volume with regard to frequencies or power.

The invention is also applicable to the placement of RFID device onluggage or baggage which is placed on airplanes. In this case, apassenger and others can always locate their baggage, provided they havean interrogator or an interrogator is used to determine the location ofeach passenger's luggage. The system can thus detect and locate luggageand baggage, or other objects, after it is in a vehicle equipped with aninterrogator.

Another feature of the invention is the use of smart antennas and asingle interrogator or reader for use in determining the location of anRFID device or object equipped therewith. Ideally, the method and systemwould use minimal energy to achieve this location-determination.

The RFID devices in any of the embodiments herein may utilize and anRFID switch, or other techniques, to limit transmissions. MIR may beused to interrogate the RFID devices.

In one embodiment, transmission via the antennas is based on thelocation of the antennas. Thus, the interrogator can control theantennas to transmit as a function of the location which is known to theinterrogator, or the processor which controls the interrogator.

For an RFID device or other device which can transmit or generate areturn signal at two or more frequencies, it is conceivable that thedistance to the RFID device from the antenna can be determined applyinga known phase relationship. With multiple antennas, the ability of anRFID device to transmit at two or more frequencies can be used to removeinteger ambiguity and thereby get a more accurate distance measurement.

Since the best position to place antennas on a shipping container orframe of another asset including an interior, object-receiving space, isnot always known in advance, a process can be implemented to find thebest location for the antennas. This process may entail arranging alarge number of antennas on the asset and conducting tests todetermining the position of RFID devices in the space. Antennas areremoved in stages and more tests conducted until the optimum number andposition of antennas for the space which provides an acceptable accuracyis determined.

RFID devices can be used in combination with SAW devices and otherwireless sensors. Many sensors are now in vehicles and many more will beinstalled in vehicles. The following disclosure is primarily concernedwith wireless sensors which can be based on MEMS, SAW and/or RFIDtechnologies. Vehicle sensors include tire pressure, temperature andacceleration monitoring sensors; weight or load measuring sensors;switches; vehicle temperature, acceleration, angular position, angularrate, angular acceleration sensors; proximity; rollover; occupantpresence; humidity; presence of fluids or gases; strain; road conditionand friction, chemical sensors and other similar sensors providinginformation to a vehicle system, vehicle operator or external site. Thesensors can provide information about the vehicle and/or its interior orexterior environment, about individual components, systems, vehicleoccupants, subsystems, and/or about the roadway, ambient atmosphere,travel conditions and external objects.

For wireless sensors, one or more interrogators can be used each havingone or more antennas that transmit energy at radio frequency, or otherelectromagnetic frequencies, to the sensors and receive modulatedfrequency signals from the sensors containing sensor and/oridentification information. One interrogator can be used for sensingmultiple switches or other devices. For example, an interrogator maytransmit a chirp form of energy at 905 MHz to 925 MHz to a variety ofsensors located within and/or in the vicinity of the vehicle. Thesesensors may be of the RFID electronic type and/or of the surfaceacoustic wave (SAW) type or a combination thereof. In the electronictype, information can be returned immediately to the interrogator in theform of a modulated backscatter RF signal. In the case of SAW devices,the information can be returned after a delay. RFID tags may alsoexhibit a delay due to the charging of the energy storage device. Onesensor can respond in both the electronic (either RFID or backscatter)and SAW-delayed modes.

When multiple sensors are interrogated using the same technology, thereturned signals from the various sensors can be time, code, space orfrequency multiplexed. For example, for the case of the SAW technology,each sensor can be provided with a different delay or a different code.Alternately, each sensor can be designed to respond only to a singlefrequency or several frequencies. The radio frequency can be amplitude,code or frequency modulated. Space multiplexing can be achieved throughthe use of two or more antennas and correlating the received signals toisolate signals based on direction.

In many cases, the sensors will respond with an identification signalfollowed by or preceded by information relating to the sensed value,state and/or property. In the case of a SAW-based or RFID-based switch,for example, the returned signal may indicate that the switch is eitheron or off or, in some cases, an intermediate state can be providedsignifying that a light should be dimmed, rather than or on or off, forexample. Alternately or additionally, an RFID based switch can beassociated with a sensor and turned on or off based on an identificationcode or a frequency sent from the interrogator permitting a particularsensor or class of sensors to be selected.

SAW devices have been used for sensing many parameters including devicesfor chemical and biological sensing and materials characterization inboth the gas and liquid phase. They also are used for measuringpressure, strain, temperature, acceleration, angular rate and otherphysical states of the environment.

Economies are achieved by using a single interrogator or even a smallnumber of interrogators to interrogate many types of devices. Forexample, a single interrogator may monitor tire pressure andtemperature, the weight of an occupying item of the seat, the positionof the seat and seatback, as well as a variety of switches controllingwindows, door locks, seat position, etc. in a vehicle. Such aninterrogator may use one or multiple antennas and when multiple antennasare used, may switch between the antennas depending on what is beingmonitored.

Similarly, the same or a different interrogator can be used to monitorvarious components of the vehicle's safety system including occupantposition sensors, vehicle acceleration sensors, vehicle angularposition, velocity and acceleration sensors, related to both frontal,side or rear impacts as well as rollover conditions. The interrogatorcould also be used in conjunction with other detection devices such asweight sensors, temperature sensors, accelerometers which are associatedwith various systems in the vehicle to enable such systems to becontrolled or affected based on the measured state.

Some specific examples of the use of interrogators and responsivedevices will now be described.

The antennas used for interrogating the vehicle tire pressuretransducers can be located outside of the vehicle passenger compartment.For many other transducers to be sensed the antennas can be located atvarious positions within passenger compartment. At least one inventionherein contemplates, therefore, a series of different antenna systems,which can be electronically switched by the interrogator circuitry.Alternately, in some cases, all of the antennas can be left connectedand total transmitted power increased.

There are several applications for weight or load measuring devices in avehicle including the vehicle suspension system and seat weight sensorsfor use with automobile safety systems. As described in U.S. Pat. Nos.4,096,740, 4,623,813, 5,585,571, 5,663,531, 5,821,425 and 5,910,647 andInternational Publication No. WO 00/65320(A1), SAW devices areappropriate candidates for such weight measurement systems, although insome cases RFID systems can also be used with an associated sensor suchas a strain gage. In this case, the surface acoustic wave on the lithiumniobate, or other piezoelectric material, is modified in delay time,resonant frequency, amplitude and/or phase based on strain of the memberupon which the SAW device is mounted. For example, the conventional boltthat is typically used to connect the passenger seat to the seatadjustment slide mechanism can be replaced with a stud which is threadedon both ends. A SAW or other strain device can be mounted to the centerunthreaded section of the stud and the stud can be attached to both theseat and the slide mechanism using appropriate threaded nuts. Based onthe particular geometry of the SAW device used, the stud can result inas little as a 3 mm upward displacement of the seat compared to a normalbolt mounting system. No wires are required to attach the SAW device tothe stud other than for an antenna.

In use, the interrogator transmits a radio frequency pulse at, forexample, 925 MHz that excites antenna on the SAW strain measuringsystem. After a delay caused by the time required for the wave to travelthe length of the SAW device, a modified wave is re-transmitted to theinterrogator providing an indication of the strain of the stud with theweight of an object occupying the seat corresponding to the strain. Fora seat that is normally bolted to the slide mechanism with four bolts,at least four SAW strain sensors could be used. Since the individual SAWdevices are very small, multiple devices can be placed on a stud toprovide multiple redundant measurements, or permit bending and twistingstrains to be determined, and/or to permit the stud to be arbitrarilylocated with at least one SAW device always within direct view of theinterrogator antenna. In some cases, the bolt or stud will be made onnon-conductive material to limit the blockage of the RF signal. In othercases, it will be insulated from the slide (mechanism) and used as anantenna.

If two longitudinally spaced apart antennas are used to receive the SAWor RFID transmissions from the seat weight sensors, one antenna in frontof the seat and the other behind the seat, then the position of the seatcan be determined eliminating the need for current seat positionsensors. A similar system can be used for other seat and seatbackposition measurements.

For strain gage weight sensing, the frequency of interrogation can beconsiderably higher than that of the tire monitor, for example. However,if the seat is unoccupied, then the frequency of interrogation can besubstantially reduced. For an occupied seat, information as to theidentity and/or category and position of an occupying item of the seatcan be obtained through the multiple weight sensors described. For thisreason, and due to the fact that during the pre-crash event, theposition of an occupying item of the seat may be changing rapidly,interrogations as frequently as once every 10 milliseconds or faster canbe desirable. This would also enable a distribution of the weight beingapplied to the seat to be obtained which provides an estimation of thecenter of pressure and thus the position of the object occupying theseat. Using pattern recognition technology, e.g., a trained neuralnetwork, sensor fusion, fuzzy logic, etc., an identification of theobject can be ascertained based on the determined weight and/ordetermined weight distribution.

There are many other methods by which SAW devices can be used todetermine the weight and/or weight distribution of an occupying itemother than the method described above and all such uses of SAW strainsensors for determining the weight and weight distribution of anoccupant are contemplated. For example, SAW devices with appropriatestraps can be used to measure the deflection of the seat cushion top orbottom caused by an occupying item, or if placed on the seat belts, theload on the belts can determined wirelessly and powerlessly. Geometriessimilar to those disclosed in U.S. Pat. No. 6,242,701 (which disclosesmultiple strain gage geometries) using SAW strain-measuring devices canalso be constructed, e.g., any of the multiple strain gage geometriesshown therein.

Generally there is an RFID implementation that corresponds to each SAWimplementation. Therefore, where SAW is used herein the equivalent RFIDdesign will also be meant where appropriate.

Although a preferred method for using the invention is to interrogateeach SAW device using wireless mechanisms, in some cases, it may bedesirable to supply power to and/or obtain information from one or moreof the SAW devices using wires. As such, the wires would be an optionalfeature.

One advantage of the weight sensors of this invention along with thegeometries disclosed in the '701 patent and herein below, is that inaddition to the axial stress in the seat support, the bending moments inthe structure can be readily determined. For example, if a seat issupported by four “legs”, it is possible to determine the state ofstress, assuming that axial twisting can be ignored, using four straingages on each leg support for a total of 16 such gages. If the seat issupported by three legs, then this can be reduced to 12 gages. Athree-legged support is preferable to four since with four legs, theseat support is over-determined which severely complicates thedetermination of the stress caused by an object on the seat. Even withthree supports, stresses can be introduced depending on the nature ofthe support at the seat rails or other floor-mounted supportingstructure. If simple supports are used that do not introduce bendingmoments into the structure, then the number of gages per seat can bereduced to three, provided a good model of the seat structure isavailable. Unfortunately, this is usually not the case and most seatshave four supports and the attachments to the vehicle not only introducebending moments into the structure but these moments vary from oneposition to another and with temperature. The SAW strain gages of thisinvention lend themselves to the placement of multiple gages onto eachsupport as needed to approximately determine the state of stress andthus the weight of the occupant depending on the particular vehicleapplication. Furthermore, the wireless nature of these gages greatlysimplifies the placement of such gages at those locations that are mostappropriate.

An additional point should be mentioned. In many cases, thedetermination of the weight of an occupant from the static strain gagereadings yields inaccurate results due to the indeterminate stress statein the support structure. However, the dynamic stresses to a first orderare independent of the residual stress state. Thus, the change in stressthat occurs as a vehicle travels down a roadway caused by dips in theroadway can provide an accurate measurement of the weight of an objectin a seat. This is especially true if an accelerometer is used tomeasure the vertical excitation provided to the seat.

Some vehicle models provide load leveling and ride control functionsthat depend on the magnitude and distribution of load carried by thevehicle suspension. Frequently, wire strain gage technology is used forthese functions. That is, the wire strain gages are used to sense theload and/or load distribution of the vehicle on the vehicle suspensionsystem. Such strain gages can be advantageously replaced with straingages based on SAW technology with the significant advantages in termsof cost, wireless monitoring, dynamic range, and signal level. Inaddition, SAW strain gage systems can be more accurate than wire straingage systems.

A strain detector in accordance with this invention can convertmechanical strain to variations in electrical signal frequency with alarge dynamic range and high accuracy even for very small displacements.The frequency variation is produced through use of a surface acousticwave (SAW) delay line as the frequency control element of an oscillator.A SAW delay line comprises a transducer deposited on a piezoelectricmaterial such as quartz or lithium niobate which is arranged so as to bedeformed by strain in the member which is to be monitored. Deformationof the piezoelectric substrate changes the frequency controlcharacteristics of the surface acoustic wave delay line, therebychanging the frequency of the oscillator. Consequently, the oscillatorfrequency change is a measure of the strain in the member beingmonitored and thus the weight applied to the seat. A SAW straintransducer can be more accurate than a conventional resistive straingage.

Other applications of weight measuring systems for an automobile includemeasuring the weight of the fuel tank or other containers of fluid todetermine the quantity of fluid contained therein.

One problem with SAW devices is that if they are designed to operate atthe GHz frequency, the feature sizes become exceeding small and thedevices are difficult to manufacture, although techniques are nowavailable for making SAW devices in the tens of GHz range. On the otherhand, if the frequencies are considerably lower, for example, in thetens of megahertz range, then the antenna sizes become excessive. It isalso more difficult to obtain antenna gain at the lower frequencies.This is also related to antenna size. One method of solving this problemis to transmit an interrogation signal in the high GHz range which ismodulated at the hundred MHz range. At the SAW transducer, thetransducer is tuned to the modulated frequency. Using a nonlinear devicesuch as a Shocky diode, the modified signal can be mixed with theincoming high frequency signal and re-transmitted through the sameantenna. For this case, the interrogator can continuously broadcast thecarrier frequency.

Devices based on RFID or SAW technology can be used as switches in avehicle as described in U.S. Pat. Nos. 6,078,252, 6,144,288 and6,748,797. There are many ways that this can be accomplished. A switchcan be used to connect an antenna to either an RFID electronic device orto a SAW device. This requires contacts to be closed by the switchactivation. An alternate approach is to use pressure from an occupant'sfinger, for example, to alter the properties of the acoustic wave on theSAW material much as in a SAW touch screen. The properties that can bemodified include the amplitude of the acoustic wave, and its phase,and/or the time delay or an external impedance connected to one of theSAW reflectors as disclosed in U.S. Pat. No. 6,084,503. In thisimplementation, the SAW transducer can contain two sections, one whichis modified by the occupant and the other which serves as a reference. Acombined signal is sent to the interrogator that decodes the signal todetermine that the switch has been activated. By any of thesetechnologies, switches can be arbitrarily placed within the interior ofan automobile, for example, without the need for wires. Since wires andconnectors are the cause of most warranty repairs in an automobile, notonly is the cost of switches substantially reduced but also thereliability of the vehicle electrical system is substantially improved.

The interrogation of switches can take place with moderate frequencysuch as once every 100 milliseconds. Either through the use of differentfrequencies or different delays, a large number of switches can be time,code, space and/or frequency multiplexed to permit separation of thesignals obtained by the interrogator. Alternately, an RF activatedswitch on some or all of the sensors can be used as discussed below.

Another approach is to attach a variable impedance device across one ofthe reflectors on the SAW device.

The impedance can therefore be used to determine the relative reflectionfrom the reflector compared to other reflectors on the SAW device. Inthis manner, the magnitude as well as the presence of a force exerted byan occupant's finger, for example, can be used to provide a ratesensitivity to the desired function. In an alternate design, as shown inU.S. Pat. No. 6,144,288, the switch is used to connect the antenna tothe SAW device. In this case, the interrogator will not get a returnfrom the SAW switch unless it is depressed.

Temperature measurement is another field in which SAW technology can beapplied and the invention encompasses several embodiments of SAWtemperature sensors.

U.S. Pat. No. 4,249,418 is one of many examples of prior art SAWtemperature sensors. Temperature sensors are commonly used withinvehicles and many more applications might exist if a low cost wirelesstemperature sensor is available such as disclosed herein. The SAWtechnology can be used for such temperature sensing tasks. These tasksinclude measuring the vehicle coolant temperature, air temperaturewithin passenger compartment at multiple locations, seat temperature foruse in conjunction with seat warming and cooling systems, outsidetemperatures and perhaps tire surface temperatures to provide earlywarning to operators of road freezing conditions. One example, is toprovide air temperature sensors in the passenger compartment in thevicinity of ultrasonic transducers used in occupant sensing systems asdescribed in U.S. Pat. No. 5,943,295, since the speed of sound in theair varies by approximately 20% from −40° C. to 85° C. Currentultrasonic occupant sensor systems do not measure or compensate for thischange in the speed of sound with the effect of reducing the accuracy ofthe systems at the temperature extremes. Through the judicious placementof SAW temperature sensors in the vehicle, the passenger compartment airtemperature can be accurately estimated and the information providedwirelessly to the ultrasonic occupant sensor system thereby permittingcorrections to be made for the change in the speed of sound.

Since the road can be either a source or a sink of thermal energy,strategically placed sensors that measure the surface temperature of atire can also be used to provide an estimate of road temperature.

Acceleration sensing is another field in which SAW technology can beapplied and the invention encompasses several embodiments of SAWaccelerometers.

U.S. Pat. Nos. 4,199,990, 4,306,456 and 4,549,436 are examples of priorart SAW accelerometers. Airbag crash sensors for determining whether thevehicle is experiencing a frontal or side impact often use micromachinedaccelerometers. These accelerometers are usually based on the deflectionof a mass which is sensed using either capacitive or piezoresistivetechnologies. SAW technology has previously not been used as a vehicleaccelerometer or for vehicle crash sensing. Due to the importance ofthis function, at least one interrogator could be dedicated to thiscritical function. Acceleration signals from the crash sensors should bereported at least preferably every 100 microseconds. In this case, thededicated interrogator would send an interrogation pulse to all crashsensor accelerometers every 100 microseconds and receive staggeredacceleration responses from each SAW accelerometer wirelessly. Thistechnology permits the placement of multiple low-cost accelerometers atideal locations for crash sensing including inside the vehicle sidedoors, in the passenger compartment and in the frontal crush zone.Additionally, crash sensors can now be located in the rear of thevehicle in the crush zone to sense rear impacts. Since the accelerationdata is transmitted wirelessly, concern about the detachment or cuttingof wires from the sensors disappears. One of the main concerns, forexample, of placing crash sensors in the vehicle doors where they mostappropriately can sense vehicle side impacts, is the fear that an impactinto the A-pillar of the automobile would sever the wires from thedoor-mounted crash sensor before the crash was sensed. This problemdisappears with the wireless technology of this invention. If twoaccelerometers are placed at some distance from each other, the rollacceleration of the vehicle can be determined and thus the tendency ofthe vehicle to rollover can be predicted in time to automatically takecorrective action and/or deploy a curtain airbag or other airbag(s).Other types of sensors such as crash sensors based on pressuremeasurements, such as supplied by Siemens, can also now be wireless.

Although the sensitivity of measurement is considerably greater thanthat obtained with conventional piezo-electric or micromachinedaccelerometers, the frequency deviation of SAW devices remains low (inabsolute value). Accordingly, the frequency drift of thermal originshould be made as low as possible by selecting a suitable cut of thepiezoelectric material. The resulting accuracy is impressive aspresented in U.S. Pat. No. 4,549,436, which discloses an angularaccelerometer with a dynamic a range of 1 million, temperaturecoefficient of 0.005%/deg F., an accuracy of 1 microradian/sec², a powerconsumption of 1 milliwatt, a drift of 0.01% per year, a volume of 1cc/axis and a frequency response of 0 to 1000 Hz. The subject matter ofthe '436 patent is hereby included in the invention to constitute a partof the invention. A similar design can be used for acceleration sensing.

In a similar manner as the polymer-coated SAW device is used to measurepressure, a device wherein a seismic mass is attached to a SAW devicethrough a polymer interface can be made to sense acceleration. Thisgeometry has a particular advantage for sensing accelerations below 1 G,which has proved to be very difficult for conventional micro-machinedaccelerometers due to their inability to both measure low accelerationsand withstand high acceleration shocks.

Gyroscopes are another field in which SAW technology can be applied andthe inventions herein encompass several embodiments of SAW gyroscopes.

SAW technology is particularly applicable for gyroscopes as described inInternational Publication No. WO 00/79217A2. The output of suchgyroscopes can be determined with an interrogator that is also used forthe crash sensor accelerometers, or a dedicated interrogator can beused. Gyroscopes having an accuracy of approximately 1 degree per secondhave many applications in a vehicle including skid control and otherdynamic stability functions. Additionally, gyroscopes of similaraccuracy can be used to sense impending vehicle rollover situations intime to take corrective action.

The inventor has represented that SAW gyroscopes of the type describedin WO 00/79217A2 have the capability of achieving accuracies approachingabout 3 degrees per hour. This high accuracy permits use of suchgyroscopes in an inertial measuring unit (IMU) that can be used withaccurate vehicle navigation systems and autonomous vehicle control basedon differential GPS corrections. Such a system is described in U.S. Pat.No. 6,370,475. An alternate preferred technology for an IMU is describedin U.S. Pat. No. 4,711,125. Such navigation systems depend on theavailability of four or more GPS satellites and an accurate differentialcorrection signal such as provided by the OmniStar Corporation, NASA orthrough the National Differential GPS system now being deployed. Theavailability of these signals degrades in urban canyon environments, intunnels and on highways when the vehicle is in the vicinity of largetrucks. For this application, an IMU system should be able to accuratelycontrol the vehicle for perhaps 15 seconds and preferably for up to fiveminutes. IMUs based on SAW technology, the technology of U.S. Pat. No.4,549,436 or of U.S. Pat. No. 4,711,125 are the best-known devicescapable of providing sufficient accuracies for this application at areasonable cost. Other accurate gyroscope technologies such as fiberoptic systems are more accurate but can be cost-prohibitive, althoughanalysis has indicated that such gyroscopes can eventually be madecost-competitive. In high volume production, an IMU of the requiredaccuracy based on SAW technology is estimated to cost less than about$100. A cost competing technology is that disclosed in U.S. Pat. No.4,711,125 which does not use SAW technology.

What follows is a discussion of the Morrison Cube of U.S. Pat. No.4,711,125 known as the QUBIK™. Typical problems that are encounteredwith sensors that try to measure multiple physical quantities at thesame time and how the QUBIK solves these problems are set forth below.

1. Problem: Errors of measurement of the linear accelerations andangular speed are mutually correlated. Even if every one of the errors,taken separately, does not accumulate with integration (the inertialsystem's algorithm does that), the cross-coupled multiplication (such asone during re-projecting the linear accelerations from one coordinatesystem to another) will have these errors detected and will make them asystematic error similar to a sensor's bias.

Solution: The QUBIK IMU is calibrated and compensated for any cross axissensitivity. For example: if one of the angular accelerometer channelshas a sensitivity to any of the three of linear accelerations, then thelinear accelerations are buffered and scaled down and summed with thebuffered angular accelerometer output to cancel out all linearacceleration sensitivity on all three angular accelerometer channels.This is important to detect pure angular rate signals. This is a verycommon practice throughout the U.S. aerospace industry to makenavigation grade IMU's. Even when individual gyroscopes andaccelerometers are used in navigation, they have their outputs scaledand summed together to cancel out these cross axis errors. Note thatcompetitive MEMS products have orders of magnitude higher cross axissensitivities when compared to navigation grade sensors and they willundoubtedly have to use this practice to improve performance MEMSangular rate sensors are advertised in degrees per second and navigationangular rate sensors are advertised in degrees per hour. MEMS angularrate sensors have high linear acceleration errors that must becompensated for at the IMU level.

2. Problem: The gyroscope and accelerometer channels require settings tobe made that contradict one another physically. For example, a gapbetween the cube and the housing for the capacitive sensors (thatmeasure the displacements of the cube) is not to exceed 50 to 100microns. On the other hand, the gyroscope channels require, in order toenhance a Coriolis effect used to measure the angular speed, that theamplitude and the linear speed of vibrations are as big as possible. Todo this, the gap and the frequency of oscillations should be increased.A greater frequency of oscillations in the nearly resonant mode requiresthe stiffness of the electromagnetic suspension to be increased, too,which leads to a worse measurement of the linear accelerations becausethe latter require that the rigidity of the suspension be minimal whenthere is a closed feedback.

Solution: The capacitive gap all around the levitated inner cube of theQUBIK is nominally 0.010 inches. The variable capacitance plates areexcited by a 1.5 MHz 25 volt peak to peak signal. The signal coming outis so strong (five volts) that there is no preamp required. Diodedetectors are mounted directly above the capacitive plates. There is noperformance change in the linear accelerometer channels when the angularaccelerometer channels are being dithered or rotated back and forthabout an axis. This was discovered by having a ground plane around theelectromagnets that eliminated transformer coupling. Dithering ordriving the angular accelerometer which rotates the inner cube proofmass is a gyroscopic displacement and not a linear displacement and hasno effect on the linear channels. Another very important point to makeis the servo loops measure the force required to keep the inner cube atits null and the servo loops are integrated to prevent anydisplacements. The linear accelerometer servo loops are not beingexercised to dither the inner cube. The angular accelerometer servo loopis being exercised. The linear and angular channels have their ownseparate set of capacitance detectors and electromagnets. Driving theangular channels has no effect on the linear ones.

The rigidity of an integrated closed loop servo is infinite at DC androlls off at higher frequencies. The QUBIK IMU measures the force beingapplied to the inner cube and not the displacement to measure angularrate. There is a force generated on the inner cube when it is beingrotated and the servo will not allow any displacement by applying equaland opposite forces on the inner cube to keep it at null. The servoreadout is a direct measurement of the gyroscopic forces on the innercube and not the displacement.

The servo gain is so high at the null position that one will not see thenull displacement but will see a current level equivalent to the forceon the cube. This is why integrated closed loop servos are so good. Theymeasure the force required to keep the inner cube at null and not thedisplacement. The angular accelerometer channel that is being ditheredwill have a noticeable displacement at its null. The sensor does nothave to be driven at its resonance. Driving the angular accelerometer atresonance will run the risk of over-driving the inner cube to the pointwhere it will bottom out and bang around inside its cavity. There is anactive gain control circuit to keep the alternating momentum constant.

Note that competitive MEMS based sensors are open loop and allowdisplacements which increase cross axis errors. MEMS sensors must havedisplacements to work and do not measure the Coriolis force, theymeasure displacement which results in huge cross axis sensitivityissues.

3. Problem: As the electromagnetic suspension is used, the sensor isgoing to be sensitive to external constant and variable (alternating)fields. Its errors will vary with its position, for example, withrespect to the Earth's magnetic field or other magnetic sources.

Solution: The earths magnetic field varies from −0.0 to +0.3 gauss andthe magnets have gauss levels over 10,000. The earth field can beshielded if necessary.

4. Problem: The QUBIT sensing element is relatively heavy so the sensoris likely to be sensitive to angular accelerations and impacts. Also,the temperature of the environment can affect the micron-sized gaps,magnetic fields of the permanent magnets, the resistance of theinductance coils etc., which will eventually increase the sensor errors.

Solution: The inner cube has a gap of 0.010 inches and does not changesignificantly over temperature.

The resistance of the coils is not a factor in the active closed loopservo. Anybody who make this statement does not know what they aretalking about. There is a stable one PPM/C current readout resistor inseries with the coil that measures the current passing through the coilwhich eliminates the temperature sensitivity of the coil resistance.

Permanent magnets have already proven themselves to be very stable overtemperature when used in active servo loops used in navigationgyroscopes and accelerometers.

Note that the sensitivity that the QUBIK IMU has achieved 0.01 degreesper hour.

5. Problem: High Cost. To produce the QUBIK, one may need to maintainmicron-sized gaps and highly clean surfaces for capacitive sensors; thedevices must be assembled in a dust-free room, and the device itselfmust be hermetic (otherwise dust or moisture will put the capacitivesensor and the electromagnetic suspension out of operation), thepermanent magnets must have a very stable performance because they'regoing to work in a feedback circuit, and so on. In our opinion, allthese issues make the technology overly complex and expensive, so anadditional metrological control will be required and no full automationcan be ever done.

Solution: The sensor does not have micron size gaps and does not need tobe hermetic unless the sensor is submerged in water! Most of the QUBIKIMU sensor is a cut out PCB's that can certainly be automated. The PCBdesign can keep dust out and does not need to be hermetic. Humidity isnot a problem unless the sensor is submerged in water. The permanentmagnets achieve parts per million stability at a cost of $0.05 each fora per system cost of under one dollar. There are may navigation gradegyroscopes and accelerometers that use permanent magnets.

Competitive MEMS sensors can have process contamination problems. To myknowledge, there are no MEMS angular rate sensors that do not requirehuman labor and/or calibration. The QUBIK IMU can instead useprogrammable potentiometers at calibration instead of human labor.

Once an IMU of the accuracy described above is available in the vehicle,this same device can be used to provide significant improvements tovehicle stability control and rollover prediction systems.

Keyless entry systems are another field in which SAW technology can beapplied and the invention encompasses several embodiments of accesscontrol systems using SAW devices.

A common use of SAW or RFID technology is for access control tobuildings however, the range of electronic unpowered RFID technology isusually limited to one meter or less. In contrast, the SAW technology,when powered or boosted, can permit sensing up to about 30 meters. As akeyless entry system, an automobile can be configured such that thedoors unlock as the holder of a card containing the SAW ID systemapproaches the vehicle and similarly, the vehicle doors can beautomatically locked when the occupant with the card travels beyond acertain distance from the vehicle. When the occupant enters the vehicle,the doors can again automatically lock either through logic or through acurrent system wherein doors automatically lock when the vehicle isplaced in gear. An occupant with such a card would also not need to havean ignition key. The vehicle would recognize that the SAW-based card wasinside vehicle and then permit the vehicle to be started by issuing anoral command if a voice recognition system is present or by depressing abutton, for example, without the need for an ignition key.

SAW sensors operating in the wireless mode can also be used to sense forice on the windshield or other exterior surfaces of the vehicle,condensation on the inside of the windshield or other interior surfaces,rain sensing, heat-load sensing and many other automotive sensingfunctions. They can also be used to sense outside environmentalproperties and states including temperature, humidity, etc.

SAW sensors can be economically used to measure the temperature andhumidity at numerous places both inside and outside of a vehicle. Whenused to measure humidity inside the vehicle, a source of water vapor canbe activated to increase the humidity when desirable and the airconditioning system can be activated to reduce the humidity whennecessary or desirable. Temperature and humidity measurements outside ofthe vehicle can be an indication of potential road icing problems. Suchinformation can be used to provide early warning to a driver ofpotentially dangerous conditions. Although the invention describedherein is related to land vehicles, many of these advances are equallyapplicable to other vehicles such as airplanes and even, in some cases,homes and buildings. The invention disclosed herein, therefore, is notlimited to automobiles or other land vehicles.

Road condition sensing is another field in which SAW technology can beapplied and the invention encompasses several embodiments of SAW roadcondition sensors.

The temperature and moisture content of the surface of a roadway arecritical parameters in determining the icing state of the roadway.Attempts have been made to measure the coefficient of friction between atire and the roadway by placing strain gages in the tire tread. Suchstrain gages are ideal for the application of SAW technology especiallysince they can be interrogated wirelessly from a distance and theyrequire no power for operation. As discussed herein, SAW accelerometerscan also perform this function. Measurement of the friction coefficient,however, is not predictive and the vehicle operator is only able toascertain the condition after the fact. Boosted SAW or RFID basedtransducers have the capability of being interrogated as much as 100feet from the interrogator. Therefore, judicious placement of low-costpowerless SAW or RFID temperature and humidity sensors in and/or on theroadway at critical positions can provide an advance warning to vehicleoperators that the road ahead is slippery. Such devices are veryinexpensive and therefore could be placed at frequent intervals along ahighway.

An infrared sensor that looks down the highway in front of the vehiclecan actually measure the road temperature prior to the vehicle travelingon that part of the roadway. This system also would not give sufficientwarning if the operator waited for the occurrence of a frozen roadway.The probability of the roadway becoming frozen, on the other hand, canbe predicted long before it occurs, in most cases, by watching the trendin the temperature. Once vehicle-to-vehicle communications are common,roadway icing conditions can be communicated between vehicles.

Some lateral control of the vehicle can also be obtained from SAWtransducers or electronic RFID tags placed down the center of the lane,either above the vehicles and/or in the roadway, for example. A vehiclehaving two receiving antennas, for example, approaching such devices,through triangulation or direct proportion, is able to determine thelateral location of the vehicle relative to these SAW devices. If thevehicle also has an accurate map of the roadway, the identificationnumber associated with each such device can be used to obtain highlyaccurate longitudinal position determinations. Ultimately, the SAWdevices can be placed on structures beside the road and perhaps on everymile or tenth of a mile marker. If three antennas are used, as discussedherein, the distances from the vehicle to the SAW device can bedetermined. These SAW devices can be powered in order to stay belowcurrent FCC power transmission limits. Such power can be supplied by aphotocell, energy harvesting where applicable, by a battery or powerconnection.

Electronic RFID tags are also suitable for lateral and longitudinalpositioning purposes, however, the range available for currentelectronic RFID systems can be less than that of SAW-based systemsunless either are powered. On the other hand, as disclosed in U.S. Pat.No. 6,748,797, the time-of-flight of the RFID system can be used todetermine the distance from the vehicle to the RFID tag. Because of theinherent delay in the SAW devices and its variation with temperature,accurate distance measurement is probably not practical based ontime-of-flight but somewhat less accurate distance measurements based onrelative time-of-arrival can be made. Even if the exact delay imposed bythe SAW device was accurately known at one temperature, such devices areusually reasonably sensitive to changes in temperature, hence they makegood temperature sensors, and thus the accuracy of the delay in the SAWdevice is more difficult to maintain. An interesting variation of anelectronic RFID that is particularly applicable to this and otherapplications of this invention is described in A. Pohl, L. Reindl, “Newpassive sensors”, Proc. 16th IEEE Instrumentation and MeasurementTechnology Conf., IMTC/99, 1999, pp. 1251-1255.

Many SAW devices are based on lithium niobate or similar strongpiezoelectric materials. Such materials have high thermal expansioncoefficients. An alternate material is quartz that has a very lowthermal expansion coefficient. However, its piezoelectric properties areinferior to lithium niobate. One solution to this problem is to uselithium niobate as the coupling system between the antenna and thematerial or substrate upon which the surface acoustic wave travels. Inthis manner, the advantages of a low thermal expansion coefficientmaterial can be obtained while using the lithium niobate for its strongpiezoelectric properties. Other useful materials such as Langasite™ haveproperties that are intermediate between lithium niobate and quartz.

The use of SAW tags as an accurate precise positioning system asdescribed above would be applicable for accurate vehicle location, asdiscussed in U.S. Pat. No. 6,370,475, for lanes in tunnels, for example,or other cases where loss of satellite lock, and thus the primaryvehicle location system, is common.

The various technologies discussed above can be used in combination. Theelectronic RFID tag can be incorporated into a SAW tag providing asingle device that provides both a quick reflection of the radiofrequency waves as well as a re-transmission at a later time. Thismarriage of the two technologies permits the strengths of eachtechnology to be exploited in the same device. For most of theapplications described herein, the cost of mounting such a tag in avehicle or on the roadway far exceeds the cost of the tag itself.Therefore, combining the two technologies does not significantly affectthe cost of implementing tags onto vehicles or roadways or side highwaystructures.

A variation of this design is to use an RF circuit such as in an RFID toserve as an energy source. One design could be for the RFID to operatewith directional antennas at a relatively high frequency such as 2.4GHz. This can be primarily used to charge a capacitor to provide theenergy for boosting the signal from the SAW sensor using circuitry suchas a circulator discussed below. The SAW sensor can operate at a lowerfrequency, such as 400 MHz, permitting it to not interfere with theenergy transfer to the RF circuit and also permit the signal to travelbetter to the receiver since it will be difficult to align the antennaat all times with the interrogator. Also, by monitoring the reception ofthe RF signal, the angular position of the tire can be determined andthe SAW circuit designed so that it only transmits when the antennas arealigned or when the vehicle is stationary. Many other opportunities nowpresent themselves with the RF circuit operating at a differentfrequency from the SAW circuit which will now be obvious to one skilledin the art.

An alternate method to the electronic RFID tag is to simply use a radaror lidar reflector and measure the time-of-flight to the reflector andback. The reflector can even be made of a series of reflecting surfacesdisplaced from each other to achieve some simple coding. It should beunderstood that RFID antennas can be similarly configured. Animprovement would be to polarize the radiation and use a reflector thatrotates the polarization angle allowing the reflector to be more easilyfound among other reflecting objects.

FIG. 11 illustrates a vehicle passenger compartment, and the enginecompartment, with multiple SAW or RFID temperature sensors 85. SAWtemperature sensors can be distributed throughout the passengercompartment, such as on the A-pillar, on the B-pillar, on the steeringwheel, on the seat, on the ceiling, on the headliner, and on thewindshield, rear and side windows and generally in the enginecompartment. These sensors, which can be independently coded withdifferent IDs and/or different delays, can provide an accuratemeasurement of the temperature distribution within the vehicle interior.RFID switches can also be used to isolate one device from another. Sucha system can be used to tailor the heating and air conditioning systembased on the temperature at a particular location in the passengercompartment. If this system is augmented with occupant sensors, then thetemperature can be controlled based on seat occupancy and thetemperature at that location. If the occupant sensor system is based onultrasonics, then the temperature measurement system can be used tocorrect the ultrasonic occupant sensor system for the speed of soundwithin the passenger compartment. Without such a correction, the errorin the sensing system can be as large as about 20 percent.

The SAW temperature sensors 85 provide the temperature at their mountinglocation to a processor unit 83 via an interrogator with the processorunit 83 including appropriate control algorithms for controlling theheating and air conditioning system based on the detected temperatures.The processor unit 83 can control, e.g., which vents in the vehicle areopen and closed, the flow rate through vents and the temperature of airpassing through the vents. In general, the processor unit 83 can controlwhatever adjustable components are present or form part of the heatingand air conditioning system.

All of the elements of the system which adjusts or controls the vehiclecomponents in any of the embodiments described herein, i.e., thesensors, processing unit and reactive system which is controlled by theprocessing unit based on the data sensed by the sensors, can be arrangedwithin the vehicle. They could be fixed to the frame of the vehicle,and/or arranged in an interior defined by the frame, with the sensorassemblies (the sensor and wireless transmission component associatedtherewith) fixed relative to the processor unit or receiver whichcontains the antenna capable of receiving the signals being transmittedwirelessly from the wireless transmission component of the sensorassemblies. In some embodiments, the sensor assemblies are arranged onparts of the vehicle which are not fixed to the frame or fixed relativeto the processor unit or receiver, such as on the tires, but in otherembodiments, the sensor assemblies are arranged only on parts fixed tothe frame. This fixed relationship between the sensor assemblies and thereceiver(s) associated with the processing unit allows for properpositioning of the receivers to communicate with all designated sensorassemblies.

In FIG. 11, a child seat 87 is illustrated on the rear vehicle seat. Thechild seat 87 can be fabricated with one or more RFID tags or SAW tags(not shown). The RFID and SAW tag(s) can be constructed to provideinformation on the occupancy of the child seat, i.e., whether a child ispresent, based on the weight, temperature, and/or any other measurableparameter. Also, the mere transmission of waves from the RFID or SAWtag(s) on the child seat 87 would be indicative of the presence of achild seat. The RFID and SAW tag(s) can also be constructed to provideinformation about the orientation of the child seat 87, i.e., whether itis facing rearward or forward. Such information about the presence andoccupancy of the child seat and its orientation can be used in thecontrol of vehicular systems, such as the vehicle airbag system orheating or air conditioning system, especially useful when a child isleft in a vehicle. In this case, a processor would control the airbag orHVAC system and would receive information from the RFID and SAW tag(s)via an interrogator.

SAW sensors also have applicability to various other sectors of thevehicle, including the powertrain, chassis, and occupant comfort andconvenience. For example, SAW and RFID sensors have applicability tosensors for the powertrain area including oxygen sensors, gear-toothHall effect sensors, variable reluctance sensors, digital speed andposition sensors, oil condition sensors, rotary position sensors, lowpressure sensors, manifold absolute pressure/manifold air temperature(MAP/MAT) sensors, medium pressure sensors, turbo pressure sensors,knock sensors, coolant/fluid temperature sensors, and transmissiontemperature sensors.

SAW sensors for chassis applications include gear-tooth Hall effectsensors, variable reluctance sensors, digital speed and positionsensors, rotary position sensors, non-contact steering position sensors,and digital ABS (anti-lock braking system) sensors. In oneimplementation, a Hall Effect tire pressure monitor comprises a magnetthat rotates with a vehicle wheel and is sensed by a Hall Effect devicewhich is attached to a SAW or RFID device that is wirelesslyinterrogated. This arrangement eliminates the need to run a wire intoeach wheel well.

FIG. 12 illustrates the placement of a variety of sensors, primarilyaccelerometers and/or gyroscopes, which can be used to diagnose thestate of the vehicle itself. Sensor 105 can be located in the headlineror attached to the vehicle roof above the side door. Typically, therecan be two such sensors one on either side of the vehicle. Sensor 106 isshown in a typical mounting location midway between the sides of thevehicle attached to or near the vehicle roof above the rear window.Sensor 109 is shown in a typical mounting location in the vehicle trunkadjacent the rear of the vehicle. One, two or three such sensors can beused depending on the application. If three such sensors are used,preferably one would be adjacent each side of vehicle and one in thecenter. Sensor 107 is shown in a typical mounting location in thevehicle door and sensor 108 is shown in a typical mounting location onthe sill or floor below the door. Sensor 110, which can be also multiplesensors, is shown in a typical mounting location forward in the crushzone of the vehicle. Finally, sensor 111 can measure the acceleration ofthe firewall or instrument panel and is located thereon generally midwaybetween the two sides of the vehicle. If three such sensors are used,one would be adjacent each vehicle side and one in the center. An IMUwould serve basically the same functions.

In general, sensors 105-111 provide a measurement of the state of thevehicle, such as its velocity, acceleration, angular orientation ortemperature, or a state of the location at which the sensor is mounted.Thus, measurements related to the state of the sensor would includemeasurements of the acceleration of the sensor, measurements of thetemperature of the mounting location as well as changes in the state ofthe sensor and rates of changes of the state of the sensor. As such, anydescribed use or function of the sensors 105-111 above is merelyexemplary and is not intended to limit the form of the sensor or itsfunction. Thus, these sensors may or may not be SAW or RFID sensors andmay be powered or unpowered and may transmit their information through awire harness, a safety or other bus or wirelessly.

Each sensor 105-111 may be single axis, double axis or triaxialaccelerometers and/or gyroscopes typically of the MEMS type. One or morecan be IMUs. These sensors 105-111 can either be wired to the centralcontrol module or processor directly wherein they would receive powerand transmit information, or they could be connected onto the vehiclebus or, in some cases, using RFID, SAW or similar technology, thesensors can be wireless and would receive their power through RF fromone or more interrogators located in the vehicle. In this case, theinterrogators can be connected either to the vehicle bus or directly tocontrol module. Alternately, an inductive or capacitive power and/orinformation transfer system can be used.

The driver can be provided with a keyless entry device, other RFID tag,smart card or cell phone with an RF transponder that can be powerless inthe form of an RFID or similar device, which can also be boosted asdescribed herein. Generally, such keyless entry devices can beconsidered a portable identification device. The interrogator, or aprocessing unit associated therewith, determines the proximity of thedriver to the vehicle door or other similar object such as a building orhouse door or vehicle trunk. As shown in FIG. 13, if a driver 118remains within a certain distance, 1 meter for example, from the door ortrunk lid 116, for example, for a certain time period such as 5 seconds,then the door or trunk lid 116 can automatically unlock and ever open insome implementations. The distance and time period can be selected ordetermined as desired. Thus, as the driver 118 approaches the trunk withhis or her arms filled with packages 117 and pauses, the trunk canautomatically open (see FIG. 14). Such a system would be especiallyvaluable for older people. This system can also be used for othersystems in addition to vehicle doors and trunk lids.

As shown in FIG. 15, an interrogator 115 is placed on the vehicle, e.g.,in the trunk 112 as shown, and transmits waves. When the keyless entrydevice 113, which contains an antenna 114 and a circuit including acirculator 135 and a memory containing a unique ID code 136, is a setdistance from the interrogator 115 for a certain duration of time, theinterrogator 115 directs a trunk opening device 137 to open the trunklid 116. The duration of time is determined from the continuousreception by the interrogator 115 of the ID code 136 from the keylessentry device 113.

A SAW device can also be used as a wireless switch as shown in FIGS. 16Aand 16B. FIG. 16A illustrates a surface 120 containing a projection 122on top of a SAW device 121. Surface material 120 could be, for example,the armrest of an automobile, the steering wheel airbag cover, or anyother surface within the passenger compartment of an automobile orelsewhere. Projection 122 will typically be a material capable oftransmitting force to the surface of SAW device 121. As shown in FIG.16B, a projection 123 may be placed on top of the SAW device 124. Thisprojection 123 permits force exerted on the projection 122 to create apressure on the SAW device 124. This increased pressure changes the timedelay or natural frequency of the SAW wave traveling on the surface ofmaterial. Alternately, it can affect the magnitude of the returnedsignal. The projection 123 is typically held slightly out of contactwith the surface until forced into contact with it.

An alternate approach is to place a switch across the IDT 127 as shownin FIG. 16C. If switch 125 is open, then the device will not return asignal to the interrogator. If it is closed, than the IDT 127 will actas a reflector sending a signal back to IDT 128 and thus to theinterrogator. Alternately, a switch 126 can be placed across the SAWdevice. In this case, a switch closure shorts the SAW device and nosignal is returned to the interrogator. For the embodiment of FIG. 16C,using switch 126 instead of switch 125, a standard reflector IDT wouldbe used in place of the IDT 127.

FIG. 16D shows an embodiment wherein a radio-frequency identificationdevice (RFID) is controlled by a switch 129A, and may be one of thewireless transmission components of a switch assembly. The switch 129Amay be a conventional, mechanical switch such as a push button, toggleand the like. A switch assembly would therefore comprise the RFID, theswitch 129A and an antenna 119A which may constitute another wirelesstransmission component. In this case, when the user presses on anexposed surface of the passenger compartment, he or she would close theswitch 129A and thereby short the RFID so that it would be inoperative.That is, the RFID would not respond when interrogated. Instead of aswitch, a variable impedance could also be provided which would modifythe output of the RFID based on the magnitude of pressure to the exposedsurface. Instead of using the switch or variable impedance, anothercontrol mechanism for causing variation in the transmission by thewireless transmission components of the switch assembly can be provided.In this embodiment, as well as the other embodiments herein wherein anRFID is provided, the RFID can be either a passive RFID or an activeRFID. In the latter case, the RFID is supplied with power from a powersource on the vehicle, such as the vehicle's battery, a local battery,photo cell, or a local energy generator or harvester.

FIGS. 16C and 16D are examples of manually activated RFID switchassemblies which could be used in a vehicular component control systemto adjust various components based on user action. For example, eachswitch assembly could control a respective component with a processorunit of the control system being coupled to or included within aninterrogator arranged to transmit RF signals having identification dataassociated with the RFID switch assemblies such that upon transmissionof each RF signal, any RFID switch assemblies with matchingidentification data would be capable of providing responsive signals. Inparticular, the RFID switch assemblies provide output based on pressureapplied by the occupant of the vehicle to an exposed surface andincludes an RF transmission component arranged to wirelessly transmit anindication of the application of pressure to the exposed surface. Thisindication may be the magnitude of the pressure being applied (e.g., viathe switch assembly of FIG. 16C) or the absence of a signal (e.g., viathe short-circuited RFID of FIG. 16D). Other input devices for use inthe same component control system include those described elsewhereherein, for example, an RFID assembly including a sensor and an RFIDswitch which could receive an RF signal from the same interrogator andupon receipt of a signal containing its identification, enabletransmission of a signal from the sensor from which a property beingmonitored by the sensor is determinable Another input device is an RFIDassembly including a sensor and an RFID switch which is arranged toreceive an RF signal from the same interrogator and upon receipt of asignal not containing its identification, disable transmission of an RFsignal from the interrogator to the sensor for its excitation, fromwhich sensor a property being monitored by the sensor is determinable.

FIG. 16H shows another switch assembly for controlling a component whichincludes an energy storage and/or transmission component 443 which maycomprise an RFID so that when the switch assembly is activated, the RFID443 is able to respond to an interrogation signal from an interrogatorassociated with the component control system. The RFID switch assemblyincludes a piezoelectric energy generator switch 441 underlying anexposed surface 440 of the vehicle and formed by a plurality of sheetsof a piezoelectric material, such as polyvinylidene fluoride (PVDF), andgenerates power upon application of pressure to the exposed surface 440.The generated power is usable to power the transmission component, i.e.,the RFID. The stack of PVDF sheets are placed over supports 442 and caninclude a snap action mechanism, not shown, to provide a snap actionswitch.

PVDF is a known inexpensive material capable of use in vehicles. PVDF isalso usable as a SAW-type device and would be especially applicablewhere there is external power provided. The presence of available energycould lead to certain advantages of the use of PVDF such as for chemicalsensing since it could be much larger than other sensing equivalents,such as lithium Niobate, and therefore more likely to capture thechemical. As an energy generator, PVDF has much more applicability sincea number of layers can be stacked thereby multiplying its energy output.The switch shown in FIG. 16H can be made, for example, so that it getsits power from someone snapping the stack of PVDF sheets 441 betweensupports 442 in a snap action switch. The power generated could send asignal to a receiver or alternatively, it could be used to power theRFID 443 thereby giving an ID transmission relating to the switchingaction which is indicative of a desired action by the occupant of thevehicle and thus could be used to control an adjustable component.

Such a PVDF switch could be used in those cases where a switching orsensing function covering a broad area is desired. The sensing of thecontact of the head with a headrest would be one example. In this case,the stack of PVDF sheets is arranged in the headrest below the coveringof the headrest and when an occupant rests his or her head against theheadrest, the PVDF sheets are compressed thereby generating power for anRFID to respond to an interrogator signal. The return signal to theinterrogator would therefore be indicative of the presence of anoccupant, or other object, resting against the headrest. Of course, manyother arrangements will be obvious to one skilled in the art.

FIG. 16E shows an embodiment wherein a surface-acoustic-wave (SAW)device is controlled by a switch 129B, and may be one of the wirelesstransmission components of a switch assembly. The switch 129B may be aconventional, mechanical switch such as a push button, toggle and thelike. A switch assembly would therefore comprise the SAW device, theswitch 129B and an antenna 119B which may constitute another a wirelesstransmission component. In this case, when the user presses on anexposed surface of the passenger compartment, he or she would close theswitch 129B and thereby prevent the SAW device from receiving a signalso that it would be inoperative. Instead of a switch, a variableimpedance could also be provided which would modify the output of theSAW device based on the magnitude of pressure to the exposed surface.Instead of using the switch or variable impedance, another controlmechanism for causing variation in the transmission buy the wirelesstransmission components of the switch assembly can be provided. In thisembodiment, as well as the other embodiments herein wherein a SAW deviceis provided, the SAW device can be either a passive SAW device or anactive SAW device. In the latter case, the SAW device is supplied withpower from a power source on the vehicle, such as the vehicle's battery,a local battery or a local energy generator or harvester.

A variable impedance is used as the control mechanism for situationswhen variations in the operation of a vehicular component are desired.For example, if a light is capable of being dimmed, then the variableimpedance would be useful to control the dimming of the light. It isalso useful to control adjustment of the volume of a sound system in thevehicle, as well as other analogue functions.

Referring now to FIG. 16F, another embodiment of the invention using acontrol mechanism, i.e., a switch or variable impedance, is an antenna139 capable of reflecting an interrogating signal, and even whichslightly modifies the interrogating signal (reflection from such anantenna being termed backscatter). The modification to the interrogatingsignal can be correlated to the desired manner for controlling thevehicular component. In this case, a lead is connected to anintermediate location on the antenna 139, e.g., the middle of theantenna 139, and a switch or variable impedance (a switch 129C is shown)is placed between the lead and ground. In the embodiment having a switch129C, when the switch 129C is open, the antenna 139 will reflect at aparticular frequency based on its length (for a simple dipole antenna).When the switch 129C is closed by the application of pressure to theexposed surface 138 of the passenger compartment, the antenna 139 willshort and thereby effectively reduce the length of the antenna 139 andalter the resonant frequency of the antenna 139. A lead placed at themiddle of the antenna 139 would, when connected to a closed switch 129Cleading to ground, cause the resonant frequency to approximately double.In the embodiment having variable impedance, the antenna would beprovided with a variable effect depending on the pressure exerted on theexposed surface or otherwise controlling the variable impedance.

Referring now to FIG. 16G, in another embodiment of a SAW sensorassembly in accordance with the invention, the circuit of the SAW sensorassembly has both an active mode and a passive mode depending on thepresence of sufficient power in the energy storage device and whetherthe substrate to which the SAW sensor assembly is associated with ismoving and thereby generates energy (for example, the energy may begenerated using the power generating system described with reference toFIG. 9 herein and FIGS. 36, 36A and 98 of U.S. patent application Ser.No. 11/681,834 incorporated by reference herein). That is, the SAWsensor assembly circuit is provided with a passive mode, which is usedwhen power is not provided to the SAW device 158 by either an energyharvester or energy generating system and the substrate (tire) is notmoving, and an active mode when power is provided or available to theSAW device 158, e.g., provided by an energy harvester or energygenerating system upon rotation of the tire or from an energy storagedevice. In the active mode (when the tire is rotating or there issufficient power in the energy storage device to power the SAW device158), a power detection circuit 157 detects power and closes a switch129E thereby connecting the SAW device 158 to the antenna 119C. Powerdetection circuit 157 may be integrated into the SAW sensor assemblycircuit so that whenever there is sufficient power being generated oravailable, the switch 129E is automatically closed. On the other hand,when energy for the SAW device 158 is not provided by an energy storagedevice and the tire is not rotating, switch 129E is open so as to avoidproviding unnecessary signals from the SAW device 158 to theinterrogator via the antenna 119C, the interrogator being used to obtainthe signals from the SAW device 158 and process them into a meaningfulreading of whatever property or properties is/are being monitored by theSAW device 158. However, since it is desirable to provide signals fromthe SAW device 158 for certain conditions of the property beingmonitored by the SAW device 158, e.g., the property is below athreshold, a sensor 156 is provided and controls a second switch 129Dbetween the antenna 119C and the SAW device 158. Sensor 156 is designedto close the switch when one or more conditions relating to the propertyare satisfied to thereby enable a transmission from the antenna 119C tothe SAW device 158 and a modified signal to be provided from the SAWdevice 158 to the antenna 119C for transmission to the interrogator.

For example, if sensor 156 is a pressure sensor and SAW assembly isbeing used to monitor tire pressure, then when the pressure is below athreshold as detected by sensor 156, switch 129D is closed and therebyallows the SAW device 158 to provide a modified signal. Sensor 156should ideally be a sensor that does not require power (or requiresminimal power) and can continually monitor the property, for example, apressure sensing diaphragm could be used to and positioned relative tothe switch 129D so that when the pressure is below a threshold, thediaphragm moves and causes closure of the switch 129D. Indeed, theswitch 129D could even be attached to such a pressure sensing diaphragm.In this case, when the pressure is at or above the threshold, thepressure sensing diaphragm does not close switch 129D thereby conservingpower. Switch 129D would therefore be in an open position whenever thepressure was at or above the design threshold. Instead of a fixedthreshold, a variable threshold can be used based on any number offactors. Also, a temperature sensor could be used to close a switch iftemperature is being monitored, e.g., a diaphragm which expands withtemperature could be attached to the switch 129D or another thermal ortemperature switch used in the circuit. Any other type of sensor whichchanges its state or condition and can cause closure of a switch basedon a predetermined threshold, or switch which is activated based on asensed property of the tire, could also be used in the invention.

The minimal transmission from the SAW device 158 is necessary inparticular in a case where only one tire has a low pressure. One reasonfor this is because it is difficult to separate transmissions from morethan one tire when operating in the passive mode.

Any of the disclosed applications can be interrogated by the centralinterrogator of this invention and can either be powered or operatedpowerlessly as described in general above. Block diagrams of threeinterrogators suitable for use in this invention are illustrated inFIGS. 19A-19C of the '834 application. FIG. 19A illustrates a superheterodyne circuit and FIG. 19B illustrates a dual super heterodynecircuit. FIG. 19C operates as follows. During the burst time twofrequencies, F1 and F1+F2, are sent by the transmitter after beinggenerated by mixing using oscillator Osc. The two frequencies are neededby the SAW transducer where they are mixed yielding F2 which ismodulated by the SAW and contains the information. Frequency (F1+F2) issent only during the burst time while frequency F1 remains on until thesignal F2 returns from the SAW. This signal is used for mixing. Thesignal returned from the SAW transducer to the interrogator is F1+F2where F2 has been modulated by the SAW transducer. It is expected thatthe mixing operations will result in about 12 db loss in signalstrength.

As discussed elsewhere herein, the particular tire that is sending asignal can be determined if multiple antennas, such as three, eachreceive the signal. For a 500 MHz signal, for example, the wave lengthis about 60 cm. If the distance from a tire transmitter to each of threeantennas is on the order of one meter, then the relative distance fromeach antenna to the transmitter can be determined to within a fewcentimeters and thus the location of the transmitter can be found bytriangulation. If that location is not a possible location for a tiretransmitter, then the data can be ignored thus solving the problem of atransmitter from an adjacent vehicle being read by the wrong vehicleinterrogator. This will be discussed below with regard to solving theproblem of a truck having 18 tires that all need to be monitored. Notealso, each antenna can have associated with it some simple circuitrythat permits it to receive a signal, amplify it, change its frequencyand retransmit it either through a wire or through the air to theinterrogator thus eliminating the need for long and expensive coaxcables.

U.S. Pat. No. 6,622,567 describes a peak strain RFID technology baseddevice with the novelty being the use of a mechanical device thatrecords the peak strain experienced by the device. Like the system ofthe invention herein, the system does not require a battery and receivesits power from the RFID circuit. The invention described herein includesuse of RFID-based sensors either in a peak strain mode or in a preferredcontinuous strain mode. This invention is not limited to measuringstrain as SAW and RFID based sensors can be used for measuring manyother parameters including chemical vapor concentration, temperature,acceleration, angular velocity etc.

One aspect of at least one of the inventions disclosed herein is the useof an interrogator to wirelessly interrogate multiple sensing devicesthereby reducing the cost of the system since such sensors are ingeneral inexpensive compared to the interrogator. The sensing devicesare preferably based on SAW and/or RFID technologies although othertechnologies are applicable.

Antenna Considerations

Antennas are a very important aspect to SAW and RFID wireless devicessuch as can be used in tire monitors, seat monitors, weight sensors,child seat monitors, fluid level sensors and similar devices or sensorswhich monitor, detect, measure, determine or derive physical propertiesor characteristics of a component in or on the vehicle or of an areanear the vehicle. In many cases, the location of a SAW or RFID deviceneeds to be determined such as when a device is used to locate theposition of a movable item in or on a vehicle such as a seat. In othercases, the particular device from a plurality of similar devices, suchas a tire pressure and/or temperature monitor that is reporting, needsto be identified. Thus, a combination of antennas can be used and thetime or arrival, angle of arrival, multipath signature or similar methodused to identify the reporting device. One preferred method is derivedfrom the theory of smart antennas whereby the signals from multipleantennas are combined to improve the signal-to-noise ratio of theincoming or outgoing signal in the presence of multipath effects, forexample.

Additionally, since the signal level from a SAW or RFID device isfrequently low, various techniques can be used to improve thesignal-to-noise ratio as described below. Finally, at the frequenciesfrequently used such as 433 MHz, the antennas can become large andmethods are needed to reduce their size. These and other antennaconsiderations that can be used to improve the operation of SAW, RFIDand similar wireless devices are described below.

Tire Information Determination

One method of maintaining a single central antenna assembly whileinterrogating all four tires on a conventional automobile, isillustrated in FIGS. 17 and 18. The same technique may be used in theinvention when interrogating multiple components, RFID devices orRFID-equipped objects as disclosed herein.

An additional antenna can be located near the spare tire, which is notshown. It should be noted that the system described below is equallyapplicable for vehicles with more than four tires such as trucks.

A vehicle body is illustrated as 620 having four tires 621 and acentrally mounted four element, switchable directional antenna array622. The four beams are shown schematically as 623 with an inactivatedbeam as 624 and the activated beam as 625. The road surface 626 supportsthe vehicle. An electronic control circuit, not shown, which may resideinside the antenna array housing 622 or elsewhere, alternately switcheseach of the four antennas of the array 622 which then sequentially, orin some other pattern, send RF signals to each of the four tires 621 andwait for the response from the RFID, SAW or similar tire pressure,temperature, ID, acceleration and/or other property monitor arranged inconnection with or associated with the tire 621. This represents a timedomain multiple access system.

The interrogator makes sequential interrogation of wheels as follows:

Stage 1. Interrogator radiates 8 RF pulses via the first RF portdirected to the 1st wheel.

-   -   Pulse duration is about 0.8 μs.    -   Pulse repetition period is about 40 μs.    -   Pulse amplitude is about 8 V (peak to peak)    -   Carrier frequency is about 426.00 MHz.    -   (Between adjacent pulses, the receiver opens its input and        receives four-pulses echoes from the transponder located in the        first wheel).    -   Then, during a time of about 8 ms, the internal micro controller        processes and stores received data    -   Total duration of this stage is 32 μs+8 ms=8.032 ms.        Stage 2, 3, 4. Interrogator repeats operations as on stage 1 for        2^(nd), 3^(rd) and 4^(th) wheel sequentially via appropriate RF        ports.        Stage 5. Interrogator stops radiating RF pulses and transfers        data stored during stages 1-4 to the external PC for final        processing and displaying. Then it returns to stage 1. The time        interval for data transfer equals about 35 ms.    -   Some notes relative to FCC Regulations:    -   The total duration of interrogation cycle of four wheels is        8.032 ms*4+35 ms=67.12 ms.    -   During this time, interrogator radiates 8*4=32 pulses, each of        0.8 μs duration.    -   Thus, average period of pulse repetition is        67.12 ms/32=2.09 ms=2090 μs    -   Assuming that duration of the interrogation pulse is 0.8 μs as        mentioned, an average repetition rate is obtained        0.8 μs/2090 μs=0.38*10⁻³    -   Finally, the radiated pulse power is        Pp=(4 V)²/(2*50 Ohm)=0.16 W    -   and the average radiated power is        Pave=0.16*0.38*10⁻³=0.42*10⁻³ W, or 0.42 mW

In another application, the antennas of the array 622 transmit the RFsignals simultaneously and space the returns through the use of a delayline in the circuitry from each antenna so that each return is spaced intime in a known manner without requiring that the antennas be switched.Another method is to offset the antenna array, as illustrated in FIG.20, so that the returns naturally are spaced in time due to thedifferent distances from the tires 621 to the antennas of the array 622.In this case, each signal will return with a different phase and can beseparated by this difference in phase using methods known to those inthe art.

In another application, not shown, two wide angle antennas can be usedsuch that each receives any four signals but each antenna receives eachsignal at a slightly different time and different amplitude permittingeach signal to be separated by looking at the return from both antennassince, each signal will be received differently based on its angle ofarrival.

Additionally, each SAW or RFID device can be designed to operate on aslightly different frequency and the antennas of the array 622 can bedesigned to send a chirp signal and the returned signals will then beseparated in frequency, permitting the four signals to be separated.Alternately, the four antennas of the array 622 can each transmit anidentification signal to permit separation. This identification can be anumerical number or the length of the SAW substrate, for example, can berandom so that each property monitor has a slightly different delaybuilt in which permits signal separation. The identification number canbe easily achieved in RFID systems and, with some difficulty and addedexpense, in SAW systems. Other methods of separating the signals fromeach of the tires 621 will now be apparent to those skilled in the art.One preferred method in particular will be discussed below and makes useof an RFID switch.

There are two parameters of SAW system, which has led to the choice of afour echo pulse system:

-   -   ITU frequency rules require that the radiated spectrum width be        reduced to:        -   Δφ≦1.75 MHz (in ISM band, F=433.92 MHz);    -   The range of temperature measurement should be from −40 F up to        +260 F.

Therefore, burst (request) pulse duration should be not less than 0.6microseconds.τ_(bur)=1/Δφ≧0.6 μs

This burst pulse travels to a SAW sensor and then it is returned by theSAW to the interrogator. The sensor's antenna, interdigital transducer(IDT), reflector and the interrogator are subsystems with a restrictedfrequency pass band. Therefore, an efficient pass band of all thesubsystems H(f)_(Σ) will be defined as product of the partial frequencycharacteristic of all components:H(f)_(Σ) =H(f)₁ *H(f)₂ * . . . H(f)i

On the other hand, the frequency H(φ)_(Σ) and a time I(τ)_(Σ) responseof any system are interlinked to each other by Fourier's transform.Therefore, the shape and duration (τ_(echo puls)) an echo signal oninput to the quadrature demodulator will differ from an interrogationpulse.

In other words, duration an echo signal on input to the quadraturedemodulator is defined as mathematical convolution of a burst signalτ_(bur.) and the total impulse response of the system I(τ)_(Σ).τ_(echo)=τ_(bur.) {circle around (x)}I(τ)_(Σ)

The task is to determine maximum pulse duration on input to thequadrature demodulator τ_(echo) under a burst pulse duration τ_(bur) of0.6 microseconds. It is necessary to consider in time all echo signals.In addition, it is necessary to take into account the following:

each subsequent echo signal should not begin earlier than the completionof the previous echo pulse. Otherwise, the signals will interfere witheach other, and measurement will not be correct;

for normal operation of available microcircuits, it is necessary thatthe signal has a flat apex with a duration not less than 0.25microseconds (τ_(meg)=t3−t2). The signal's phase will be constant onlyon this segment;

the total sensor's pass band (considering double transit IDT and itsantenna as a reflector) constitutes 10 MHz;

the total pass band of the interrogator constitutes no more than 4 MHz.

Conducting the corresponding calculations yields the determination thatduration of impulse front (t2−t1=t4−t3) constitutes about 0.35microseconds. Therefore, total duration of one echo pulse is not lessthawτ_(echo)=(t2−t1)+τ_(meg.)+(t4−t3)=0.35+0.25+0.35=0.95 μs

Hence, the arrival time of each following echo pulse should be notearlier than 1.0 microsecond. This conclusion is very important.

In Appendix 1 of the '139 application, it is shown that for correcttemperature measuring in the required band it is necessary to meet thefollowing conditions:(T2−T1)=1/(72*10−6 1/° K*(125° C.−(−40° C.))*434.92*106)=194 ns

This condition is outrageous. If to execute ITU frequency rules, theband of correct temperature measuring will be reduced five times:(125° C.−(−40° C.)*194 ns)/1000 ns=32° C.=58° F.

This is the main reason that it is necessary to add the fourth echopulse in a sensor. The principle purpose of the fourth echo pulse is tomake the temperature measurement unambiguous in a wide interval oftemperatures when a longer interrogation pulse is used (the respectivetime intervals between the sensor's echo pulses are also longer). Amathematical model of the processing of a four-pulse echo that explainsthese statements is presented in Appendix 3 of the '139 application.

The duration of the interrogation pulse and the time positions of thefour pulses are calculated as:T1>4*τ_(echo)=4.00 μsT1=T1+τ_(echo)=5.00 μsT3=T2+τ_(echo)=6.00 μsT4=T3+τ_(echo)+0.08 μs=7.08 μs

The sensor's design with four pulses is exhibited in FIGS. 25 and 26 ofthe '834 application.

-   -   τ_(bur) 0.60 μs    -   T1 4.00 μs    -   T2 5.00 μs    -   T3 6.00 μs    -   T4 7.08 μs

The reason that such a design was selected is that this design providesthree important conditions:

1. It has the minimum RF signal propagation loss. Both SAW waves use formeasuring (which are propagated to the left and to the right from IDT).

2. All parasitic echo signals (signals of multiple transits) areeliminated after the fourth pulse. For example, the pulse is excited bythe IDT, then it is reflected from a reflector No. 1 and returns to theIDT. The pulse for the second time is re-emitted and it passes thesecond time on the same trajectory. The total time delay will be 8.0microseconds in this case.

3. It has the minimum length.

Although the discussion herein concerns the determination of tireinformation, the same system can be used to determine the location ofseats, the location of child seats when equipped with sensors,information about the presence of object or chemicals in vehicularcompartments and the like.

Smart Antennas

Some of the shortcomings in today's wireless products can be overcome byusing smart antenna technology. A smart antenna is a multi-elementantenna that significantly improves reception by intelligently combiningthe signals received at each antenna element and adjusting the antennacharacteristics to optimize performance as the transmitter or receivermoves and the environment changes.

Smart antennas can suppress interfering signals, combat signal fadingand increase signal range thereby increasing the performance andcapacity of wireless systems.

A method of separating signals from multiple tires, for example, is touse a smart antenna such as that manufactured by Motia. This particularMotia device is designed to operate at 433 MHz and to mitigate multipathsignals at that frequency. The signals returning to the antennas fromtires, for example, contain some multipath effects that, especially ifthe antennas are offset somewhat from the vehicle center, are differentfor each wheel. Since the adaptive formula will differ for each wheel,the signals can be separated (see “enhancing 802.11 WLANs through SmartAntennas”, January 2004 available at motia.com). The following is takenfrom that paper.

“Antenna arrays can provide gain, combat multipath fading, and suppressinterfering signals, thereby increasing both the performance andcapacity of wireless systems. Smart antennas have been implemented in awide variety of wireless systems, where they have been demonstrated toprovide a large performance improvement. However, the various types ofspatial processing techniques have different advantages anddisadvantages in each type of system.”

“This strategy permits the seamless integration of smart antennatechnology with today's legacy WLAN chipset architecture. Since the802.11 system uses time division duplexing (the same frequency is usedfor transmit and receive), smart antennas can be used for both transmitand receive, providing a gain on both uplink and downlink, using smartantennas on either the client or access point alone. Results show a 13dB gain with a four element smart antenna over a single antenna systemwith the smart antenna on one side only, and an 18 dB gain with thesmart antenna on both the client and access point. Thus, this“plug-and-play” adaptive array technology can provide greater range,average data rate increases per user, and better overall coverage.

“In the multibeam or phased array antenna, a beamformer forms severalnarrow beams, and a beam selector chooses the beam for reception thathas the largest signal power. In the adaptive array, the signal isreceived by several antenna elements, each with similar antennapatterns, and the received signals are weighted and combined to form theoutput signal. The multibeam antenna is simpler to implement as thebeamformer is fixed, with the beam selection only needed every fewseconds for user movement, while the adaptive array must calculate thecomplex beamforming weights at least an order of magnitude faster thanthe fading rate, which can be several Hertz for pedestrian users.”

“Finally, there is pattern diversity, the use of antenna elements withdifferent patterns. The combination of these types of diversity permitsthe use of a large number of antennas even in a small form factor, suchas a PCMCIA card or handset, with near ideal performance”

Through its adaptive beamforming technology, Motia has developedcost-effective smart antenna appliqués that vastly improve wirelessperformance in a wide variety of wireless applications including Wi-Fithat can be incorporated into wireless systems without majormodifications to existing products. Although the Motia chipset has beenapplied to several communication applications, it has yet to be appliedto all of the monitoring applications as disclosed in the currentassignee's patents and pending patent applications, and in particularvehicular monitoring applications such as tire monitoring.

The smart antenna works by determining a set of factors or weights thatare used to operate on the magnitude and/or phase of the signals fromeach antenna before the signals are combined. However, since thegeometry of a vehicle tire relative to the centralized antenna arraydoes not change much as the tire rotates, but is different for eachwheel, the weights themselves contain the information as to which tiresignal is being received. In fact, the weights can be chosen to optimizesignal transmission from a particular tire thus providing a method ofselectively interrogating each tire at the maximum antenna gain.

Distributed Load Monopole

Antenna developments in the physics department at the University ofRhode Island have resulted in a new antenna technology. The antennasdeveloped called DLM's (Distributed loaded monopole) are smallefficient, wide bandwidth antennas. The simple design exhibits 50-ohmimpedance and is easy to implement. They require only a direct feed froma coax cable and require no elaborate matching networks.

The prime advantage to this technology is a substantial reduction of thesize of an antenna. Typically, the DLM antenna is about ⅓ the size of anormal dipole with only minor loss in efficiency. This is especiallyimportant for vehicle applications where space is always at a premium.Such antennas can be used for a variety of vehicle radar andcommunication applications as well for the monitoring of RFID, SAW andsimilar devices on a vehicle and especially for tire pressure,temperature, and/or acceleration monitoring as well as other monitoringpurposes. Such applications have not previously been disclosed.

Although the DLM is being applied to several communication applications,it has yet to be applied to all of the monitoring applications asdisclosed in the current assignee's patents and pending patentapplications. The antenna gain that results and the ability to packseveral antennas into a small package are attractive features of thistechnology.

Plasma Antenna

The following disclosure was taken from “Markland Technologies—GasPlasma”: (www.marklandtech.com)

“Plasma antenna technology employs ionized gas enclosed in a tube (orother enclosure) as the conducting element of an antenna. This is afundamental change from traditional antenna design that generallyemploys solid metal wires as the conducting element. Ionized gas is anefficient conducting element with a number of important advantages.Since the gas is ionized only for the time of transmission or reception,“ringing” and associated effects of solid wire antenna design areeliminated. The design allows for extremely short pulses, important tomany forms of digital communication and radars The design furtherprovides the opportunity to construct an antenna that can be compact anddynamically reconfigured for frequency, direction, bandwidth, gain andbeamwidth. Plasma antenna technology will enable antennas to be designedthat are efficient, low in weight and smaller in size than traditionalsolid wire antennas.”

“When gas is electrically charged, or ionized to a plasma state itbecomes conductive, allowing radio frequency (RF) signals to betransmitted or received. We employ ionized gas enclosed in a tube as theconducting element of an antenna. When the gas is not ionized, theantenna element ceases to exist. This is a fundamental change fromtraditional antenna design that generally employs solid metal wires asthe conducting element. We believe our plasma antenna offers numerousadvantages including stealth for military applications and higherdigital performance in commercial applications. We also believe ourtechnology can compete in many metal antenna applications.”

“Initial studies have concluded that a plasma antenna's performance isequal to a copper wire antenna in every respect. Plasma antennas can beused for any transmission and/or modulation technique: continuous wave(CW), phase modulation, impulse, AM, FM, chirp, spread spectrum or otherdigital techniques. And the plasma antenna can be used over a largefrequency range up to 20 GHz and employ a wide variety of gases (forexample neon, argon, helium, krypton, mercury vapor and xenon). The sameis true as to its value as a receive antenna.”

“Plasma antenna technology has the following additional attributes:

-   -   No antenna ringing provides an improved signal to noise ratio        and reduces multipath signal distortion.    -   Reduced radar cross section provides stealth due to the        non-metallic elements.    -   Changes in the ion density can result in instantaneous changes        in bandwidth over wide dynamic ranges.    -   After the gas is ionized, the plasma antenna has virtually no        noise floor.    -   While in operation, a plasma antenna with a low ionization level        can be decoupled from an adjacent high-frequency transmitter.    -   A circular scan can be performed electronically with no moving        parts at a higher speed than traditional mechanical antenna        structures.    -   It has been mathematically illustrated that by selecting the        gases and changing ion density that the electrical aperture (or        apparent footprint) of a plasma antenna can be made to perform        on par with a metal counterpart having a larger physical size.    -   Our plasma antenna can transmit and receive from the same        aperture provided the frequencies are widely separated.    -   Plasma resonance, impedance and electron charge density are all        dynamically reconfigurable. Ionized gas antenna elements can be        constructed and configured into an array that is dynamically        reconfigurable for frequency, beamwidth, power, gain,        polarization and directionality—on the fly.    -   A single dynamic antenna structure can use time multiplexing so        that many RF subsystems can share one antenna resource reducing        the number and size of antenna structures.”

Several of the characteristics discussed above are of particularusefulness for several of the inventions herein including the absence ofringing, the ability to turn the antenna off after transmission and thenimmediately back on for reception, the ability to send very shortpulses, the ability to alter the directionality of the antenna and tosweep thereby allowing one antenna to service multiple devices such astires and to know which tire is responding. Additional advantagesinclude, smaller size, the ability to work with chirp, spread spectrumand other digital technologies, improved signal to noise ratio, widedynamic range, circular scanning without moving parts, and antennasharing over differing frequencies, among others.

Some of the applications disclosed herein can use ultra widebandtransceivers. UWB transceivers radiate most of the energy with itsfrequency centered on the physical length of the antenna. With the UWBconnected to a plasma antenna, the center frequency of the UWBtransceiver could be hopped or swept simultaneously.

A plasma antenna can solve the problem of multiple antennas by changingits electrical characteristic to match the function required—Time domainmultiplexed. It can be used for high-gain antennas such as phase array,parabolic focus steering, log periodic, yogi, patch quadrafiler, etc.One antenna can be used for GPS, ad-hoc (such as car-to-car)communication, collision avoidance, back up sensing, cruse control,radar, toll identification and data communications.

Although the plasma antennas are being applied to several communicationapplications, they have yet to be applied to the monitoring applicationsas disclosed herein. The many advantages that result and the ability topack several antenna functions into a small package are attractivefeatures of this technology. Patents and applications that discussplasma antennas include: U.S. Pat. No. 6,710,746 and U.S. Pat. App. PubNos. 20030160742 and 20040130497.

Dielectric Antenna

A great deal of work is underway to make antennas from dielectricmaterials. In one case, the electric field that impinges on thedielectric is used to modulate a transverse electric light beam. Inanother case, the reduction of the speed of electro magnetic waves dueto the dielectric constant is used to reduce the size of the antenna. Itcan be expected that developments in this area will affect the antennasused in cell phones as well as in RFID and SAW-based communicationdevices in the future. Thus, dielectric antennas can be advantageouslyused with some of the inventions disclosed herein.

Nanotube Antenna

Antennas made from carbon nanotubes are beginning to show promise ofincreasing the sensitivity of antennas and thus increasing the range forcommunication devices based on RFID, SAW or similar devices where thesignal strength frequently limits the range of such devices. The use ofthese antennas is therefore contemplated herein for use in tire monitorsand the other applications disclosed herein.

Combinations of the above antenna designs in many cases can benefit fromthe advantages of each type to add further improvements to the field.Thus the inventions herein are not limited to any one of the aboveconcepts nor is it limited to their use alone. Where feasible, allcombinations are contemplated herein.

Antenna Summary

A general system for obtaining information about a vehicle or acomponent thereof or therein is illustrated in FIG. 19 and includesmultiple sensors 627 which may be arranged at specific locations on thevehicle, on specific components of the vehicle, on objects temporarilyplaced in the vehicle such as child seats, or on or in any other objectin or on the vehicle or in its vicinity about which information isdesired. The sensors 627 may be SAW or RFID sensors or other sensorswhich generate a return signal upon the detection of a transmitted radiofrequency signal. A multi-element antenna array 622 is mounted on thevehicle, in either a central location as shown in FIG. 17 or in anoffset location as shown in FIG. 20, to provide the radio frequencysignals which cause the sensors 627 to generate the return signals.

A control system 628 is coupled to the antenna array 622 and controlsthe antennas in the array 622 to be operative as necessary to enablereception of return signals from the sensors 627. There are several waysfor the control system 628 to control the array 622, including to causethe antennas to be alternately switched on in order to sequentiallytransmit the RF signals therefrom and receive the return signals fromthe sensors 627 and to cause the antennas to transmit the RF signalssimultaneously and space the return signals from the sensors 627 via adelay line in circuitry from each antennas such that each return signalis spaced in time in a known manner without requiring switching of theantennas. The control system can also be used to control a smart antennaarray.

The control system 628 also processes the return signals to provideinformation about the vehicle or the component. The processing of thereturn signals can be any known processing including the use of patternrecognition techniques, neural networks, fuzzy systems and the like.

The antenna array 622 and control system 628 can be housed in a commonantenna array housing 630.

Once the information about the vehicle or the component is known, it isdirected to a display/telematics/adjustment unit 629 where theinformation can be displayed on a display 629 to the driver, sent to aremote location for analysis via a telematics unit 629 and/or used tocontrol or adjust a component on, in or near the vehicle. Althoughseveral of the figures illustrate applications of these technologies totire monitoring, it is intended that the principles and devicesdisclosed can be applied to the monitoring of a wide variety ofcomponents on and off a vehicle.

In summary, the use of devices capable of reading or scanning RFIDdevices when situated in compartments or spaces defined by vehicles orother mobile assets provides significant advantages. Among other things,it allows for the determination of the identification and location ofthe RFID devices and thus objects equipped with such RFID devices, andwith a communications or telematics unit coupled to the interrogator, itallows for communication of that information off of the vehicle, i.e.,to one or more remote sites. The overall system identifies the RFIDdevice if it generates a unique identification code, which is usuallythe case, and thus can generate a transmission to the remote sitecontaining an identification of an object in a space of a mobile asset.

With the foregoing system, it is possible at the remote site to locateand monitor the RFID-equipped object.

Alternative or in addition to the communication to a remote site, theinterrogator could also transmit or otherwise provide the signal with anidentification of the object to another system on the vehicle itself. Inthis manner, someone looking for an RFID-equipped object in a spacecould easily determine its location, such as a package delivery driverlooking for a specific package in a truck or an airline worker lookingfor a specific passenger's luggage.

Referring now to FIGS. 21-24, additional aspects of the monitoring ofinterior contents of a shipping container, trailer, boat, shed, etc.will now be described. Generally, these contents can be removed from thevehicle and thus are usually not directly attached to a frame of thevehicle which defines the object-containing interior. Such a frame mayhave the form of a truck, a truck trailer, a shipping container, a boat,an airplane or another vehicle.

Commercial systems are now available from companies such as Skybitz Inc.45365 Vintage Park Plaza, Suite 210, Dulles, Va. 20166-6700, which willmonitor the location of an asset anywhere on the surface of the earth.Each monitored asset contains a low cost GPS receiver and a satellitecommunication system. The system can be installed onto a truck, trailer,container, or other asset and it well periodically communicate with alow earth orbit (LEO) or a geostationary satellite providing thesatellite with its location as determined by the GPS receiver or asimilar system such as the Skybitz Global Locating System (GLS). Theentire system operates off of a battery, for example, and if the systemtransmits information to the satellite once per day, the battery canlast many years before requiring replacement. Thus, the system canmonitor the location of a trailer, for example, once per day, which issufficient if trailer is stationary. The interrogation rate can beautomatically increased if the trailer begins moving. Such a system canlast for 2 to 10 years without requiring maintenance depending ondesign, usage and the environment. Even longer periods are possible ifpower is periodically or occasionally available to recharge the batterysuch as by vibration energy harvesting, solar cells, capacitivecoupling, inductive coupling, RF or vehicle power. In some cases, anultracapacitor as discussed above can be used in place of a battery.

The Skybitz system by itself only provides information as to thelocation of a container and not information about its contents,environment, and/or other properties. At least one of the inventionsdisclosed herein disclosed here is intended to provide this additionalinformation, which can be coded typically into a few bytes and sent tothe satellite along with the container location information andidentification. First, consider monitoring of the interior contents of acontainer. From here on, the terms “shipping container” or “container”will be used as a generic cargo holder and will include all cargoholders including standard and non-standard containers, boats, trucks,trailers, sheds, warehouses, storage facilities, tanks, buildings or anyother such object that has space and can hold cargo. Most of these“containers” are also vehicles as defined above.

Consider now a standard shipping container that is used for shippingcargo by boat, trailer, or railroad, such cargo being usually inanimate,i.e., not alive. Such containers are nominally 8′w×8′h×20′ or 40′ longoutside dimensions, however, a container 48′ in length is also sometimesused. The inside dimensions are frequently around 4″ less than theoutside dimensions. In a simple interior container monitoring system,one or more ultrasonic transducers can be mounted on an interior part ofthe container adjacent the container's ceiling in a protective housing.Periodically, the ultrasonic transducers can emit a few cycles ofultrasound and receive reflected echoes of this ultrasound from wallsand contents of the trailer. In some cases, especially for longcontainers, one or more transducers, typically at one end of thecontainer, can send to one or more transducers located at, for example,the opposite end. Usually, however, the transmitters and receivers arelocated near each other. Due to the long distance that the ultrasoundwaves must travel especially in the 48 foot container, it is frequentlydesirable to repeat the send and receive sequence several times and toadd or average the results. This has the effect of improving the signalto noise ratio. Note that the system disclosed herein and in the parentpatents and applications is able to achieve such long sensing distancesdue to the principles disclosed herein. Competitive systems that are nowbeginning to enter the market have much shorter sensing distances andthus a key invention herein is the ability to achieve sensing distancesin excess of 20 feet.

Note that in many cases several transducers are used for monitoring thevehicle such as a container that typically point in slightly differentdirections. This need not be the case and a movable mounting is alsocontemplated where the motion is accomplished by any convenient methodsuch as a magnet, motor, etc.

Referring to FIG. 21, a container 480 is shown including an interiorsensor system 481 arranged to obtain information about contents in theinterior of the container 480. The interior sensor system includes awave transmitter 482 mounted at one end of the container 480 and whichoperatively transmits waves into the interior of the container 480 and awave receiver 483 mounted adjacent the wave transmitter 482 and whichoperatively receives waves from the interior of the container 480. Asshown, the transmitter 482 and receiver 483 are adjacent one another butsuch a positioning is not intended to limit the invention. Thetransmitter 482 and receiver 483 can be formed as a single transducer ormay be spaced apart from one another. Multiple pairs oftransmitter/receivers can also be provided, for example transmitter 482′and receiver 483′ are located at an opposite end of the container 480proximate the doors 484.

The interior sensor system 481 includes a processor coupled to thereceiver 483, and optionally the transmitter 482, and which is residenton the container 480, for example, in the housing of the receiver 483 orin the housing of a communication system 485. The processor isprogrammed to compare waves received by each receiver 483, 483′ atdifferent times and analyze either the received waves individually orthe received waves in comparison to or in relation to other receivedwaves for the purpose of providing information about the contents in theinterior of the container 480. The processor can employ patternrecognition techniques and as discussed more fully below, be designed tocompensate for thermal gradients in the interior of the container 480.Information about the contents of the container 480 may comprise thepresence or motion of objects in the interior. The processor may beassociated with a memory unit which can store data on the location ofthe container 480 and the analysis of the data from the interior sensorsystem 481.

The container 480 also includes a location determining system 486 whichmonitors the location of the container 480. To this end, the locationdetermining system can be any asset locator in the prior art, whichtypically include a GPS receiver, transmitter and appropriate electronichardware and software to enable the position of the container 480 to bedetermined using GPS technology or other satellite or ground-basedtechnology including those using the cell phone system or similarlocation based systems.

The communication system 485 is coupled to both the interior sensorsystem 481 and the location determining system 486 and transmits theinformation about the contents in the interior of the container 480(obtained from the interior sensor system 481) and the location of thecontainer 480 (obtained from the location determining system 486). Thistransmission may be to a remote facility wherein the information aboutthe container 480 is stored, processed, counted, reviewed and/ormonitored and/or retransmitted to another location, perhaps by way ofthe Internet.

Briefly, in this regard, transmission of the data about the container480 and its contents, may be transmitted to the remote location via theInternet, e.g., the ubiquitous Internet. The transmission may includethe location of the container 480 or sufficient information obtainedfrom a data reception unit, e.g., in the cell phone or PDA (see thediscussion about FIG. 25) to enable the location of the container 480 tobe determined at the remote location.

This data may be strengths of satellite signals being received at thecontainer 480, or signals from wireless beacons having known positions.The teachings of U.S. Pat. No. 6,243,648 can be incorporated to enhancethe location determination. The communication system 485 would determinethe minimum time needed to get enough satellite information to allow thecomputer at the remote location to determine the location of thevehicle.

The container 480 also includes a door status sensor 487 arranged todetect when one or both doors 484 is/are opened or closed after havingbeen opened. The door status sensor 487 may be an ultrasonic sensorwhich is positioned a fixed distance from the doors 484 and registerschanges in the position of the doors 484. Alternately, other door statussystems can be used such as those based on switches, magnetic sensors orother technologies. The door status sensor 487 can be programmed toassociate an increase in the distance between the sensor 487 and each ofthe doors 484 and a subsequent decrease in the distance between thesensor 487 and that door 484 as an opening and subsequent closing ofthat door 484. In the alternative, a latching device can be provided todetect latching of each door 484 upon its closure. The door statussensor 487 is coupled to the interior sensor system 481, or at least tothe transmitters 482,482′ so that the transmitters 482,482′ can bedesigned to transmit waves into the interior of the container 480 onlywhen the door status sensor 487 detects when at least one door 484 isclosed after having been opened. For other purposes, the ultrasonicsensors may be activated on opening of the door(s) in order to monitorthe movement of objects into or out of the container, which might inturn be used to activate an RFID or bar code reading system or otherobject identification system.

When the ultrasonic transducers are first installed into the container480 and the doors 484 closed, an initial pulse transmission can beinitiated and the received signal stored to provide a vector of datathat is representative of an empty container. To initiate the pulsetransmission, an initiation device or function is provided in theinterior sensor system 481, e.g., the door status sensor 487. At asubsequent time when contents have been added to the container (aspossibly reflected in the opening and closing of the doors 484 asdetected by the door status sensor 487), the ultrasonic transducers canbe commanded to again issue a few cycles of ultrasound and record thereflections. If the second pattern is subtracted from the first pattern,or otherwise compared, in the processor the existence of additionalcontents in the container 480 will cause the signal to change, whichthus causes the differential signal to change and the added contentsdetected. Vector as used herein with ultrasonic systems is a lineararray of data values obtained by rectifying, taking the envelope anddigitizing the returned signal as received by the transducer or otherdigital representation comprising at least a part of the returnedsignal.

-   -   Another use of the door status sensor 487 is to cause storage of        data about the contents in the container 480 as a function of        opening and closing of the doors 484. Thus, the memory unit        would store data indicating each time the doors 484 are opened        and closed and the contents of the container 480 before and        after each opening and closing. This will provide information        about the loading and unloading of the contents from the        container 480. Data about the contents of the container 480 may        be obtained in any of the ways described herein, including using        sensor systems 491 placed on each object in the interior of the        container 480.

When a container 480 is exposed to sunlight on its exterior top, astable thermal gradient can occur inside the container 480 where the topof the container 480 near the ceiling is at a significantly highertemperature than the bottom of the container 480. This thermal gradientchanges the density of the gas inside the container causing it to act asa lens to ultrasound that diffracts or bends the ultrasonic waves andcan significantly affect the signals sensed by the receiver portions483,483′ of the transducers. Thus, the vector of sensed data when thecontainer is at a single uniform temperature will look significantlydifferent from the vector of sensed data acquired within the samecontainer when thermal gradients are present.

It is even possible for currents of heated air to occur within acontainer 480 if a side of the container is exposed to sunlight. Sincethese thermal gradients can substantially affect the vector, the systemmust be examined under a large variety of different thermalenvironments. This generally requires that the electronics be designedto mask somewhat the effects of the thermal gradients on the magnitudeof the sensed waves while maintaining the positions of these waves intime. This can be accomplished as described in above-referenced patentsand patent applications through the use, for example, of a logarithmiccompression circuit. There are other methods of minimizing the effect onthe reflected wave magnitudes that will accomplish substantially thesame result some of which are disclosed elsewhere herein.

When the complicating aspects of thermal gradients are taken intoaccount, in many cases a great deal of data must be taken with a largenumber of different occupancy situations to create a database of perhaps10,000 to one million vectors each representing the different occupancystate of the container in a variety of thermal environments. This datacan then be used to train a pattern recognition system such as a neuralnetwork, modular or combination neural network, cellular neural network,support vector machine, fuzzy logic system, Kalman filter system, sensorfusion system, data fusion system or other classification system. Sinceall containers of the type transported by ships, for example, are ofstandard sizes, only a few of these training exercises need to beconducted, typically one for each different geometry container. Theprocess of adapting an ultrasonic occupancy monitoring system to acontainer or other space is described for automobile interior monitoringin above-referenced patents and patent applications, and therefore thisprocess is not repeated here.

Other kinds of interior monitoring systems can be used to determine andcharacterize the contents of a space such as a container. One exampleuses a scanner and photocell 488, as in a laser radar system, and can bemounted near the floor of the container 480 and operated to scan thespace above the floor in a plane located, for example, 10 cm above thefloor. Since the distance to a reflecting wall of the container 480 canbe determined and recorded for each angular position of the scanner, thedistance to any occupying item will show up as a reflection from anobject closer to the scanner and therefore a shadow graph of thecontents of the container 10 cm above the floor can be obtained and usedto partially categorize the contents of the container 480.Categorization of the contents of the container 480 may involve the useof pattern recognition technologies. Other locations of such a scanningsystem are possible.

In both of these examples, relatively little can be the about thecontents of the container other then that something is present or thatthe container is empty. Frequently this is all that is required. A moresophisticated system can make use of one or more imagers (for examplecameras) 489 mounted near the ceiling of the container, for example.Such imagers can be provided with a strobe flash and then commanded tomake an image of the trailer interior at appropriate times. The outputfrom such an imager 489 can also be analyzed by a pattern recognitionsystem such as a neural network or equivalent, to reduce the informationto a few bytes that can be sent to a central location via an LEO orgeostationary satellite, for example. As with the above ultrasonicexample, one image can be subtracted from the empty container image andif anything remains then that is a representation of the contents thathave been placed in the container. Also, various images can besubtracted to determine the changes in container contents when the doorsare opened and material is added or removed or to determine changes inposition of the contents. Various derivatives of this information can beextracted and sent by the telematics system to the appropriate locationfor monitoring or other purposes.

Each of the systems mentioned above can also be used to determinewhether there is motion of objects within the container relative to thecontainer. Motion of objects within the container 480 would be reflectedas differences between the waves received by the transducers (indicativeof differences in distances between the transducer and the objects inthe container) or images (indicative of differences between the positionof objects in the images). Such motion can also aid in imagesegmentation which in turn can aid in the object identification process.This is particularly valuable if the container is occupied by life formssuch as humans.

In the system of FIG. 21, wires (not shown) are used to connect thevarious sensors and devices. It is contemplated that all of the units inthe monitoring system can be coupled together wirelessly, using forexample the Bluetooth, WI-FI or other protocol. Thus, any type or formof wired, wireless or combination network can be used to connect thesensors and other parts of the monitoring arrangement together on theasset.

If an inertial device 490 is also incorporated, such as the MEMSIC dualaxis accelerometer, which provides information as to the accelerationsof the container 480, then this relative motion can be determined by theprocessor and it can be ascertained whether this relative motion iscaused by acceleration of the container 480, which may indicate loosecargo, and/or whether the motion is caused by the sensed occupying item.In latter case, a conclusion can perhaps be reached that container isoccupied by a life form such as an animal or human.

Additionally, it may be desirable to place sensors on an item of cargoitself since damage to the cargo could occur from excessiveacceleration, shock, temperature, vibration, etc. regardless of whetherthe same stimulus was experienced by the entire container. A loose itemof cargo, for example, may be impacting the monitored item of cargo anddamaging it. Thus, any of the sensors described herein, e.g., chemicalsensors, motion sensors and the like, can be placed on each item ofcargo or object and connected by wires or wirelessly to a receiving unitwhich receives data obtained by such object-mounted sensors. Dataobtained from the sensors may be communicated to a remote facility.Also, the obtaining of the data can be done periodically or triggered byany of the triggers described for obtaining data via the asset-mountedsensor systems.

Relative motion can also be sensed in some cases from outside of thecontainer through the use of accelerometers, microphones or MIR(Micropower Impulse Radar). Note that all such sensors regardless ofwhere they are placed are contemplated herein and are part of thepresent inventions.

Chemical sensors 491 based on surface acoustic wave (SAW) or othertechnology can in many cases be designed to sense the presence ofcertain vapors in the atmosphere and can do so at very low power. Aproperly designed SAW or equivalent sensing device, for example, canmeasure acceleration, angular rate, strain, temperature, pressure,carbon dioxide concentration, humidity, hydrocarbon concentration, andthe presence or concentration of many other chemicals. A separate SAW orsimilar device may be needed for each chemical species (or in some caseseach class of chemicals) where detection is desired. The devices,however, can be quite small and can be designed to use very littlepower. Such a system of SAW or equivalent devices can be used to measurethe existence of certain chemical vapors in the atmosphere of thecontainer, or the atmosphere around an object in the interior of acontainer, much like a low power electronic nose. In some cases, it canbe used to determine whether a carbon dioxide source such as a human isin the container, or in the object. Such chemical sensing devices canalso be designed, for example, to monitor for many other chemicalsincluding some narcotics, hydrocarbons, mercury vapor, and otherhazardous chemicals including some representative vapors of explosivesor some weapons of mass destruction. With additional research, SAW orsimilar devices can also be designed or augmented to sense the presenceof radioactive materials, and perhaps some biological materials such assmallpox or anthrax. In many cases, such SAW devices do not now exist,however, researchers believe that given the proper motivation that suchdevices can be created. Thus, although heretofore not appreciated, SAWor equivalent based systems can monitor a great many dangerous andhazardous materials that may be either legally or illegally occupyingspace within a container, for example. In particular, the existence ofspills or leakages from the cargo can be detected in time to perhapssave damage to other cargo either within the container or in an adjacentcontainer. Although SAW devices have in particular been described, otherlow power devices using battery or RF power can also be used wherenecessary. Note, the use of any of the aforementioned SAW devices inconnection within or on a vehicle for any purpose other than tirepressure and temperature monitoring or torque monitoring is new andcontemplated by the inventions disclosed herein. Only a small number ofexamples are presented of the general application of the SAW, or RFID,technology to vehicles.

Other sensors that can be designed to operate under very low powerlevels include microphones 492 and light sensors 493 or sensorssensitive to other frequencies in the electromagnetic spectrum as theneed arises. The light sensors 493 could be designed to cause activationof the interior sensor system 481 when the container is being switchedfrom a dark condition (normally closed) to a light situation (when thedoor or other aperture is opened). A flashlight could also activate thelight sensor 493.

Instead of one or more batteries providing power to the interior sensorsystem 481, the communication system 485 and the location determiningsystem 486, solar power can be used. In this case, one or more solarpanels 494 are attached to the upper wall of the container 480 (see FIG.57) and electrically coupled to the various power-requiring componentsof the monitoring system. A battery can thus be eliminated. In thealternative, since the solar panel(s) 494 will not always be exposed tosunlight, a rechargeable battery can be provided which is charged by thesolar panel 494 when the solar panels are exposed to sunlight. A batterycould also be provided in the event that the solar panel 494 does notreceive sufficient light to power the components of the monitoringsystem. In a similar manner, power can temporarily be supplied by avehicle such as a tractor either by a direct connection to the tractorpower or through capacitive, inductive or RF coupling power transmissionsystems. As above, an ultracapacitor can be used instead of a batteryand energy harvesting can be used if there is a source of energy such aslight or vibration in the environment.

In some cases, a container is thought to be empty when in fact it isbeing surreptitiously used for purposes beyond the desires of thecontainer owner or law enforcement authorities. The various transducersthat can be used to monitor interior of a container as described above,plus others, can also be used to allow the trailer or container owner toperiodically monitor the use of his property.

Immediately above, monitoring of the interior of the container isdescribed. If the container is idle, there may not the need tofrequently monitor the status of the container interior or exterioruntil some event happens. Thus, all monitoring systems on the containercan be placed in the sleep mode until some event such as a motion orvibration of the container takes place. Other wakeup events couldinclude the opening of the doors, the sensing of light or a change inthe interior temperature of the container above a reference level, forexample. When any of these chosen events occurs, the system can beinstructed to change the monitoring rate and to immediately transmit asignal to a satellite or another communication system, or respond to asatellite-initiated signal for some LEO-based, or geocentric systems,for example. Such an event may signal to the container owner that arobbery was in progress either of the interior contents of the containeror of the entire container. It also might signal that the contents ofthe container are in danger of being destroyed through temperature orexcessive motion or that the container is being misappropriated for someunauthorized use.

FIG. 22 shows a flowchart of the manner in which container 480 may bemonitored by personnel or a computer program at a remote facility forthe purpose of detecting unauthorized entry into the container andpossible theft of the contents of the container 480. Initially, thewakeup sensor 495 detects motion, sound, light or vibration includingmotion of the doors 484, or any other change of the condition of thecontainer 480 from a stationary or expected position. The wakeup sensor495 can be designed to provide a signal indicative of motion only aftera fixed time delay, i.e., a period of “sleep”. In this manner, thewakeup sensor would not be activated repeatedly in traffic stop and gosituations.

The wakeup sensor 495 initiates the interior sensor system 481 toperform the analysis of the contents in the interior of the container,e.g., send waves into the interior, receive waves and then process thereceived waves. If motion in the interior of the container is notdetected at 496, then the interior sensor system 481 may be designed tocontinue to monitor the interior of the container, for example, byperiodically re-sending waves into the interior of the container. Ifmotion is detected at 496, then a signal is sent at 497 to a monitoringfacility via the communication system 485 and which includes thelocation of the container 480 obtained from the location determiningsystem 486 or by the ID for a permanently fixed container or otherasset, structure or storage facility. In this manner, if the motion isdetermined to deviate from the expected handling of the container 480,appropriate law enforcement personnel can be summoned to investigate.

When it is known and expected that the container should be in motion,monitoring of this motion can still be important. An unexpectedvibration could signal the start of a failure of the chassis tire, forexample, or failure of the attachment to the chassis or the attachmentof the chassis to the tractor. Similarly, an unexpected tilt angle ofthe container may signify a dangerous situation that could lead to arollover accident and an unexpected shock could indicate an accident hasoccurred. Various sensors that can be used to monitor the motion of thecontainer include gyroscopes, accelerometers and tilt sensors. An IMU(Inertial Measurement Unit) containing for example three accelerometersand three gyroscopes can be used.

In some cases, the container or the chassis can be provided with weightsensors that measure the total weight of the cargo as well as thedistribution of weight. By monitoring changes in the weight distributionas the vehicle is traveling, an indication can result that the contentswithin the trailer are shifting which could cause damage to the cargo.An alternate method is to put weight sensors in the floor or as a mat onthe floor of the vehicle. The mat design can use the bladder principlesdescribed above for weighing b vehicle occupants using, in most cases,multiple chambers. Strain gages can also be configured to measure theweight of container contents. An alternate approach is to use inertialsensors such as accelerometers and gyroscopes to measure the motion ofthe vehicle as it travels. If the characteristics of the inputaccelerations (linear and angular) are known from a map, for example, orby measuring them on the chassis then the inertial properties of thecontainer can be determined and thus the load that the containercontains. This is an alternate method of determining the contents of acontainer. If several (usually 3) accelerometers and several (usually 3)gyroscopes are used together in a single package then this is known asan inertial measurement unit. If a source of position is also known suchas from a GPS system then the errors inherent in the IMU can becorrected using a Kalman filter.

Other container and chassis monitoring can include the attachment of atrailer to a tractor, the attachment of electrical and/or communicationconnections, and the status of the doors to the container. If the doorsare opened when this is not expected, this could be an indication of acriminal activity underway. Several types of security seals areavailable including reusable seals that indicate when the door is openor closed or if it was ever opened during transit, or single use sealsthat are destroyed during the process of opening the container.

Referring now to FIG. 23C, another application of monitoring the entireasset would be to incorporate a diagnostic module 472 into the asset.Frequently, the asset may have operating parts, e.g., if it is arefrigerated and contains a refrigeration unit 470. To this end, sensors474, e.g., temperature sensors, can be installed on the asset andmonitored using pattern recognition techniques embodied in a processorof the diagnostic module 472, as disclosed in U.S. Pat. No. 5,809,437and U.S. Pat. No. 6,175,787. As such, various sensors 474 would beplaced on the container 480 and used to determine problems with thecontainer 480 or refrigeration unit 470 which might cause it to operateabnormally, e.g., if the refrigeration unit were about to fail becauseof a refrigerant leak. Sensors 474 would indicate a higher temperaturethan expected if the refrigeration unit 470 were not operating normallyIn this case, the information about the expected failure of therefrigeration unit 470 could be transmitted to a facility, via a linkbetween the diagnostic module 472 and the communications system 485, andmaintenance of the refrigeration unit could be scheduled, e.g., based onthe location of the personnel capable of fixed or replacing therefrigeration unit 470 and the location of the asset which is alsotransmitted by the communications unit 485. Instead of using sensors 474apart from the refrigeration unit 470, or other operating part whoseoperating is being diagnosed, to determine abnormal operation, it isalso possible to connect the diagnostic module 472 to the refrigerationunit 470 so that it can directly monitor the operation thereof, thisconnection being represented by a line in FIG. 23C.

It is anticipated that whatever entity is monitoring a plurality ofassets could strategically locate personnel capable of fixing orreplacing abnormally operating parts of the asset to ensure securecarriage of the goods in the asset, e.g., perishable products. Thus,when the asset provides a signal indicative of abnormal operation andits location to the remote facility, personnel at the remote facilitycould dispatch the nearest personnel to attend to the asset.

It can also be desirable to detect unauthorized entry into container,which could be by cutting with a torch, or motorized saw, grinding, orblasting through the wall, ceiling, or floor of the container. Thisevent can be detected by one or more of the following methods:

1. A light sensor which measures any part of the visible or infraredpart of the spectrum and is calibrated to the ambient light inside thecontainer when the door is closed and which then triggers when light isdetected above ambient levels and door is closed.

2. A vibration sensor attached to wall of container which triggers onvibrations of an amplitude and/or frequency signature indicative offorced entry into the container. The duration of signal would also be afactor to consider. The algorithm could be derived from observations andtests or it could use a pattern recognition approach such as NeuralNetworks.

3. An infrared or carbon dioxide sensor could be used to detect humanpresence, although a carbon dioxide sensor would probably require aprolonged exposure.

4. Various motion sensors as discussed above can also be used, but wouldneed to be resistant to triggering on motion typical of cargo transport.Thus a trained pattern recognition algorithm might be necessary.

5. The Interior of the container can be flooded with waves (ultrasonicor electromagnetic) and the return signature evaluated by a patternrecognition system such as a neural network trained to recognize changesconsistent with the removal of cargo or the presence of a person orpeople. Alternately the mere fact that the pattern was changing could beindicative of human presence.

As discussed above and below, information from entry/person detectorcould be sent to communication network to notify interested parties ofcurrent status. Additionally, an audible alarm may be sounded and aphoto could also be taken to identify the intruder. Additionally, motionsensors such as an accelerometer on a wall or floor of a vehicle such asa container or an ultrasonic or optical based motion detector such asused to turn on residential lights and the like, can also be used todetect intrusion into a vehicle and thus are contemplated herein. Suchsensors can be mounted at any of the preferred locations disclosedherein or elsewhere in or on the vehicle. If a container, for example,is closed, a photocell connected to a pattern recognition system such asa neural network, for example can be trained to be sensitive to veryminute changes in light such as would occur when an intruder opens adoor or cuts a hole in a wall, ceiling or the floor of a vehicle even ona dark night. Even if there are holes in the vehicle that allow light toenter, the rate of change of this illumination can be detected and usedas an indication of an intrusion.

It is noteworthy that systems based on the disclosure above can beconfigured to monitor construction machinery to prevent theft or atleast to notify others that a theft is in progress.

The transmission of data obtained from imagers, or other transducers, toanother location, requiring the processing of the information, usingneural networks for example, to a remote location is an importantfeature of the inventions disclosed herein. This capability can permitan owner of a cargo container or truck trailer to obtain a picture ofthe interior of the vehicle at any time via telematics. When coupledwith occupant sensing, the driver of a vehicle can be recognized and theresult sent by telematics for authorization to minimize the theft orunauthorized operation of a vehicle. The recognition of the driver caneither be performed on the vehicle or an image of the driver can be sentto a remote location for recognition at that location.

Generally monitoring of containers, trailers, chassis etc. isaccomplished through telecommunications primarily with LEO orgeostationary satellites or through terrestrial-based communicationsystems. These systems are commercially available and will not bediscussed here. Expected future systems include communication betweenthe container and the infrastructure to indicate to the monitoringauthorities that a container with a particular identification number ispassing a particular terrestrial point. If this is expected, then noaction would be taken. The container identification number can be partof a national database that contains information as to the contents ofthe container. Thus, for example, if a container containing hazardousmaterials approaches a bridge or tunnel that forbids such hazardousmaterials from passing over the bridge or through the tunnel, then anemergency situation can be signaled and preventive action taken.

It is expected that monitoring of the transportation of cargo containerswill dramatically increase as the efforts to reduce terrorist activitiesalso increase. If every container that passes within the borders of theUnited States has an identification number and that number is in adatabase that provides the contents of that container, then the use ofshipping containers by terrorists or criminals should gradually beeliminated. If these containers are carefully monitored by satellite oranother communication system that indicates any unusual activity of acontainer, an immediate investigation can result and then the cargotransportation system will gradually approach perfection whereterrorists or criminals are denied this means of transporting materialinto and within the United States. If any container is found containingcontraband material, then the entire history of how that containerentered the United States can be checked to determine the source of thefailure. If the failure is found to have occurred at a loading portoutside of the United States, then sanctions can be imposed on the hostcountry that could have serious effects on that country's ability totrade worldwide. Just the threat of such an action would be asignificant deterrent. Thus, the use of containers to transporthazardous materials or weapons of mass destruction as well as people,narcotics, or other contraband and can be effectively eliminated throughthe use of the container monitoring system of at least one of theinventions disclosed herein.

Prior to the entry of a container ship into a harbor, a Coast Guard boatfrom the U.S. Customs Service can approach the container vessel and scanall of the containers thereon to be sure that all such containers areregistered and tracked including their contents. Where containerscontain dangerous material legally, the seals on those containers can becarefully investigated prior to the ship entering U.S. waters.Obviously, many other security precautions can now be conceived once theability to track all containers and their contents has been achievedaccording to the teachings of at least one of the inventions disclosedherein.

Containers that enter the United States through land ports of entry canalso be interrogated in a similar fashion. As long as the shipper isknown and reputable and the container contents are in the database,which would probably be accessible over the Internet, is properlyupdated, then all containers will be effectively monitored that enterthe United States with the penalty of an error resulting in thedisenfranchisement of the shipper, and perhaps sanctions against thecountry, which for most reputable shippers or shipping companies wouldbe a severe penalty sufficient to cause such shippers or shippingcompanies to take appropriate action to assure the integrity of theshipping containers. Intelligent selected random inspections guided bythe container history would still take place.

Although satellite communication is preferred, communication using cellphones and infrastructure devices placed at appropriate locations alongroadways are also possible. Eventually there will be a network linkingall vehicles on the highways in a peer-to-peer arrangement (perhapsusing Bluetooth, IEEE 802.11 (WI-FI), Wi-Mobile or other local, mesh orad-hoc network) at which time information relative to container contentsetc. can be communicated to the Internet or elsewhere through thispeer-to-peer network. It is expected that a pseudo-noise-based orsimilar communication system such as a code division multiple access(CDMA) system, wherein the identifying code of a vehicle is derived fromthe vehicle's GPS determined location, will be the technology of choicefor this peer-to-peer vehicle network. It is expected that this networkwill be able to communicate such information to the Internet (withproper security precautions including encryption where necessary ordesired) and that all of the important information relative to thecontents of moving containers throughout the United States will beavailable on the Internet on a need-to-know basis. Thus, law enforcementagencies can maintain computer programs that will monitor the contentsof containers using information available from the Internet. Similarly,shippers and receivers can monitor the status of their shipments througha connection onto the Internet. Thus, the existence of the Internet orequivalent can be important to the monitoring system described herein.

An alternate method of implementing the invention is to make use of acell phone or PDA. Cell phones that are now sold contain a GPS-basedlocation system as do many PDAs. Such a system along with minimaladditional apparatus can be used to practice the teachings disclosedherein. In this case, the cell phone, PDA or similar portable devicecould be mounted through a snap-in attachment system, for example,wherein the portable device is firmly attached to the vehicle. Thedevice can at that point, for example, obtain an ID number from thecontainer through a variety of methods such as a RFID, SAW or hardwiredbased system. It can also connect to a satellite antenna that wouldpermit the device to communicate to a LEO or GEO satellite system, suchas Skybitz as described above. Since the portable device would onlyoperate on a low duty cycle, the battery should last for many days orperhaps longer. Of course, if it is connected to the vehicle powersystem, its life could be indefinite. When power is waning, this factcan be sent to the satellite or cell phone system to alert theappropriate personnel. Since a cell phone contains a microphone, itcould be trained, using an appropriate pattern recognition system, torecognize the sound of an accident or the deployment of an airbag orsimilar event. It thus becomes a very low cost OnStar® type telematicssystem.

As an alternative to using a satellite network, the cell phone networkcan be used in essentially the same manner when a cell phone signal isavailable. All of the sensors disclosed herein can either beincorporated into the portable device or placed on the vehicle andconnected to the portable device when the device is attached to thevehicle. This system has a key advantage of avoiding obsolescence. Withtechnology rapidly changing, the portable device can be exchanged for alater model or upgraded as needed or desired, keeping the overall systemat the highest technical state. Existing telematics systems such asOnStar® can of course also be used with this system.

Importantly, an automatic emergency notification system can now be madeavailable to all owners of appropriately configured cell phones, PDAs,or other similar portable devices that can operate on a very low costbasis without the need for a monthly subscription since they can bedesigned to operate only on an exception basis. Owners would pay only asthey use the service. Stolen vehicle location, automatic notification inthe event of a crash even with the transmission of a picture forcamera-equipped devices is now possible. Automatic door unlocking canalso be done by the device since it could transmit a signal to thevehicle, in a similar fashion as a keyless entry system, from eitherinside or outside the vehicle. The phone can be equipped with abiometric identification system such as fingerprint, voice print, facialor iris recognition etc. thereby giving that capability to vehicles. Thedevice can thus become the general key to the vehicle or house, and caneven open the garage door etc. If the cell phone is lost, itswhereabouts can be instantly found since it has a GPS receiver and knowswhere it is. If it is stolen, it will become inoperable without thebiometric identification from the owner.

Other communication systems will also frequently be used to connect thecontainer with the chassis and/or the tractor and perhaps theidentification of the driver or operator. Thus, information can beavailable on the Internet showing what tractor, what trailer, whatcontainer and what driver is operating at a particular time, at aparticular GPS location, on a particular roadway, with what particularcontainer contents. Suitable security will be provided to ensure thatthis information is not freely available to the general public.Redundancy can be provided to prevent the destruction or any failure ofa particular site from failing the system.

This communication between the various elements of the shipping systemwhich are co-located (truck, trailer, container, container contents,driver etc.) can be connected through a wired or wireless bus such asthe CAN bus. Also, an electrical system such as disclosed in U.S. Pat.No. 5,809,437, U.S. Pat. No. 6,175,787 and U.S. Pat. No. 6,326,704 canalso be used in the invention.

In many cases, it is desirable to obtain and record additionalinformation about the cargo container and its contents. As mentionedabove, the weight of the container with its contents and thedistribution and changes in this weight distribution could be valuablefor a safety authority investigating an accident, for highwayauthorities monitoring gross vehicle weight, for container owners whocharge by the used capacity, and others. The environment that thecontainer and its contents have been subjected to could also besignificant information. Such things as whether the container wasflooded, exposed to a spill or leakage of a hazardous material, exposedto excessive heat or cold, shocks, vibration etc. can be importanthistorical factors for the container affecting its useful life,establishing liability for damages etc. For example, a continuousmonitoring of container interior temperature could be significant forperishable cargo and for establishing liability.

With reference to FIG. 23A, in some cases, the individual cargo items498 can be tagged with RFID or SAW tags 499 (also representing a generalsensor system used to obtain data about the cargo item 498) and thepresence of this cargo in the container 480 could be valuableinformation to the owner of the cargo. One or more sensors on thecontainer that periodically read RFID tags could be required, such asone or more RFID interrogators 500 which periodically send a signalwhich will cause the RFID tags 499 to generate a responsive signal. Theresponsive signal generated by the RFID tags 499 will containinformation about the cargo item on which the RFID tag 499 is placed.This information may be any property or condition about the contents,such as temperature, presence of one or more chemicals, pressure, aradioactivity sensor, and other types of sensors discussed elsewhereherein.

Multiple interrogators or at least multiple antennas may be requireddepending on the size of the container. The RFID can be based on a SAWthus providing greater range for a passive system or it can also beprovided with an internal battery or ultracapacitor for even greaterrange. Energy harvesting can also be used if appropriate.

Similarly, for certain types of cargo, a barcode system mightacceptable, or another optically readable identification code. The cargoitems would have to be placed so that the identification codes arereadable, i.e., when a beam of light is directed over the identificationcodes, a pattern of light is generated which contains information aboutthe cargo item. As shown in FIG. 23B, the cargo items in this case areboxes having an equal height so that a space remains between the top ofthe boxes 501 and the ceiling of the container 480. One or more opticalscanners 502, including a light transmitter and receiver, are arrangedon the ceiling of the container and can be arranged to scan the uppersurfaces of the boxes 503, possibly by moving the length of thecontainer 480, or through a plurality of such sensors. During such ascan, patterns of light are reflected from the barcodes 501 on the uppersurfaces of the boxes 503 and received by the optical scanner 502. Thepatterns of light contain information about the cargo items in the boxes503. Receivers can be arranged at multiple locations along the ceiling.Other arrangements to ensure that a light beam traverses a barcode 501and is received by a receiver can also be applied in accordance with theinvention. As discussed above, other tag technologies can be used ifappropriate such as those based of magnetic wires.

By monitoring the data being determined using the sensors on the cargoitems 498, this data can be analyzed by a processor on the cargo items498 themselves, e.g., as part of the sensor system 499, or separate fromthe cargo items 498, e.g., on the container 480 (see processor 506 inFIG. 59A wherein the processor 506 is close to the RFID interrogator500), to determine the presence of a condition which has or is likely toaffect the status or health of the cargo items 498 has occurred or isforecast to occur. That is, the processor 506 determines whether thereis a problem with the cargo items 498 or a potential problem. As anexample, one problem is when a motion sensor is part of the sensorsystem 499 and motion of the cargo item 498 is analyzed relative tomotion of the container 480, and the processor 506 determines that thecargo item is moving considerably more than the container 480, whichsituation could be indicative of the cargo item 498 not being properlyrestrained and thus liable to fall over and cause damage to the cargoitem 498. Analysis of data obtained by the sensor systems 491 todetermine the existence or potential for a problem with the cargo item498 may involve use of pattern recognition technologies, such as atrained neural network.

The communication system 485 may be programmed to transmit a message toa remote facility only when the processor determines the presence of aproblem or potential problem with one or more cargo items 498. Thiswould conserve energy. Additionally, or alternatively, the sensorsystems 491 could be designed to trigger to obtain data about the cargoitem 498 when a door of the asset is closed after having been opened, achange in light in the interior of the container 480 is detected, basedon a predetermined or variable initiation time being regulated by aninitiation device, motion of the container 480 or change in motion ofthe container 480 is detected, vibration of the container 480 isdetected, and a predetermined internal or external event occurs whichwarrants obtaining data about the contents in view of the possibility ofa change in the status or health of the contents. In one embodiment, thesensor systems 491 on the cargo items 498 can be triggered to obtaineddata from the remote facility via the communication system 485, or frompersonnel on or about the vehicle on which the container 480 issituated.

When sensors are placed on each cargo item 498, the sensors are coupledto the communication system 485 and the location determining system 486using wires or wirelessly or a combination of both. If needed, apeer-to-peer and/or a mesh network can be integrated into the asset,i.e., the frame thereof, to enable all sensors on cargo items 498arranged in the interior of the asset to communicate with thecommunication system 485. This would most likely be applicable for largeships, trains and airplanes.

The ability to read barcodes and RFID tags provides the capability ofthe more closely tracking of packages for such organizations as UPS,Federal Express, the U.S. Postal Service and their customers. Now, insome cases, the company can ascertain that a given package is in fact ona particular truck or cargo transporter and also know the exact locationof the transporter.

Frequently, a trailer or container has certain hardware such as racksfor automotive parts, for example, that are required to stay with thecontainer. During unloading of the cargo these racks, or othersub-containers, could be removed from the container and not returned. Ifthe container system knows to check for the existence of these racks,then this error can be eliminated. Frequently, the racks are of greatervalue then the cargo they transport. Using RFID tags and a simpleinterrogator mounted on the ceiling of the container perhaps near theentrance, enables monitoring of parts that are taken in or are removedfrom the container and associated with the location of container. Bythis method, pilferage of valuable or dangerous cargo can at least betracked.

Containers constructed in accordance with the invention will frequentlyhave a direct method of transmitting information to a satellite.Typically, the contents of the container are more valuable than thetruck or chassis for the case of when the container is not a trailer. Ifthe tractor, train, plane or ship that is transporting the container isexperiencing difficulties, then this information can be transmitted tothe satellite system and thus to the container, carrier, or cargo owneror agent for attention. Information indicating a problem with carrier(railroad, tractor, plane, boat) may be sensed and reported onto a bussuch as CAN bus which can be attached either wirelessly or by wires tothe container. Alternately, sensors on the container can determinethrough vibrations etc. that the carrier may be experiencing problems.The reporting of problems with the vehicle can come from dedicatedsensors or from a general diagnostic system such as described in U.S.Pat. No. 5,809,437 and U.S. Pat. No. 6,175,787, and herein. Whatever thesource of the diagnostic information, especially when valuable ordangerous cargo is involved, this information in coded form can betransmitted to a ground station, LEO or geostationary satellite asdiscussed above. Other information that can be recorded by containerincludes the identification of the boat, railroad car, or tractor andoperator or driver.

The experiences of the container can be recorded over time as acontainer history record to help in life cycle analysis to determinewhen a container needs refurbishing, for example. This history in codedform could reside on a memory that is resident on the container orpreferably the information can be stored on a computer file associatedwith that container in a database. The mere knowledge of where acontainer has been, for example, may aid law enforcement authorities todetermine which containers are most likely to contain illegalcontraband.

The pertinent information relative to a container can be stored on a tagthat is associated and physically connected to the container. This tagmay be of the type that can be interrogated remotely to retrieve itscontents. Such a tag, for example, could contain information as to whenand where the container was most recently opened and the contents of thecontainer. Thus, as containers enter a port, their tags can each beinterrogated to determine their expected contents and also to give awarning for those containers that should be inspected more thoroughly.In most cases, the tag information will not reside on the container butin fact will be on a computer file accessible by those who have anauthorization to interrogate the file. Thus, the container need onlyhave a unique identification number that cannot easily be destroyed,changed or otherwise tampered with. These can be visual and painted onthe outside of the container or an RFID, barcode or other objectidentification system can be used. Again, the tags can be based onpassive SAW technology to give greater range or could contain a batteryor ultracapacitor for even greater range. The tag can be in a sleep modeuntil receiving a wakeup call to further conserve battery power.

FIG. 24 shows a flow chart of the manner in which multiple assets may bemonitored using a data processing and storage facility 510, each assethaving a unique identification code. The location of each asset isdetermined at 511, along with one or more properties or characteristicsof the contents of each asset at 512, one or more properties of theenvironment of each asset at 513, and/or the opening and/or closing ofthe doors of each asset at 514. This information is transmitted to thedata processing and storage facility 510 as represented by 515 with theidentification code. Information about the implement being used totransport the asset and the individual(s) or company or companiesinvolved in the transport of the asset can also be transmitted to thefacility as represented by 516. This latter information could be enteredby an input device attached to the asset.

The data processing and storage facility 510 is connected to theInternet at 517 to enable shippers 518 to check the location andprogress of the asset, the contents of the asset, the environment of theasset, whether the doors are being opened and closed impermissibly andthe individual and companies handling the asset. The same information,or a subset of this information, can also be accessed by law enforcementpersonnel at 519 and maritime/port authorities at 520. Differententities can be authorized to access different items of information orsubsets of the total information available relating to each asset.

For anti-theft purposes, the shipper enters the manifest of the assetusing an input device 521 so that the manifest can be compared to thecontents of the asset (at 522). A determination is made at 523 as towhether there are any differences between the current contents of theasset and the manifest. For example, the manifest might indicate thepresence of contents whereas the information transmitted by the assetreveals that it does not contain any objects. When such a discrepancy isrevealed, the shipment can be intercepted at 524 to ascertain thewhereabouts of the cargo. The history of the travels of the asset wouldalso be present in the data facility 510 so that it can be readilyascertained where the cargo disappeared. If no discrepancy is revealed,the asset is allowed to proceed at 525.

Having the ability to transmit coded information to a satellite, orother telematics system, using a low cost device having a battery thatlasts for many years opens up many other, previously impracticalopportunities. Many of these opportunities are discussed above and belowand all are teachings of at least one of the inventions disclosedherein. In this section, opportunities related to monitoring theenvironment in the vicinity of the container will be discussed. Manytypes of sensors can be used for the purpose of exterior monitoringincluding ultrasound, imagers such as cameras both with and withoutillumination including visual, infrared or ultraviolet imagers, radar,scanners including laser radar and phased array radar, other types ofsensors which sense other parts of the electromagnetic spectrum,capacitive sensors, electric or magnetic field sensors, and chemicalsensors among others.

Cameras either with or without a source of illumination can be used torecord people approaching the container and perhaps stealing thecontents of the container. At the appropriate frequencies, (tetra Hertz,for example) the presence of concealed weapons can be ascertained asdescribed in Alien Vision: Exploring the Electromagnetic Spectrum WithImaging Technology (SPIE Monograph Vol. PM104) by Austin Richards.Infrared sensors can be used to detect the presence of animal lifeincluding humans in the vicinity of container. Radio frequency sensorscan sense the presence of authorized personnel having a keyless entrytype transmitter or a SAW, RFID or similar device of the proper design.In this way, the container can be locked as a safe, for example, andonly permit an authorized person carrying the proper identification toopen the container or other storage facility.

A pattern recognition system can be trained to identify facial or irispatterns, for example, of authorized personnel or ascertain the identityof authorized personnel to prevent theft of the container. Such apattern recognition system can operate on the images obtained by thecameras. That is, if the pattern recognition system is a neural network,it would be trained to identify or ascertain the identity of authorizedpersonnel based on images of such personnel during a training phase andthus operationally only allow such personnel to open the container,enter the container and/or handle the container.

A wide variety of smart cards, biometric identification systems (such asfingerprints, voice prints and Iris scans) can be used for the samepurpose. When an unauthorized person approaches the container, his orher picture can be taken and in particular, if sensors determine thatsomeone is attempting to force entry into the container, that person'spicture can be relayed via the communication system to the properauthorities. Cameras with a proper pattern recognition system can alsobe used to identify if an approaching person is wearing a disguise suchas a ski mask or is otherwise acting in a suspicious manner Thisdetermination can provide a critical timely warning and in some casespermit an alarm to be sounded or otherwise notify the properauthorities.

Capacitance sensors or magnetic sensors can be used to ascertain thatthe container is properly attached to a trailer. An RFID or barcodescanner on the container can be used to record the identification of thetractor, trailer, or other element of the transportation system. Theseare just a small sampling of the additional sensors that can be usedwith the container or even mounted on a tractor or chassis to monitorthe container. With the teachings of at least one of the inventionsdisclosed herein, the output of any of these sensors can now betransmitted to a remote facility using a variety of telematics methodsincluding communication via a low power link to a satellite, such asprovided by the Skybitz Corporation as described above and others.

Thus, as mentioned above, many new opportunities now exist for applyinga wide variety of sensors to a cargo container or other object asdiscussed above and below. Through a communication system such as a LEOor geostationary or other satellite system, critical information aboutthe environment of container or changes in that environment can betransmitted to the container owner, law enforcement authorities,container contents owner etc. Furthermore, the system is generally lowcost and does not require connection to an external source of power. Thesystem generally uses low power from a battery that can last for yearswithout maintenance,

Many of the sensor systems described above output data that can best beanalyzed using pattern recognition systems such as neural networks,cellular neural networks, fuzzy logic, sensor fusion, modular neuralnetworks, combination neural networks, support vector machines, neuralfuzzy systems or other classifiers that convert the pattern data into anoutput indicative of the class of the object or event being sensed. Oneinteresting method, for example, is the ZISC® chip system of SiliconRecognition Inc., Petaluna, Calif. A general requirement for the lowpower satellite monitoring system is that the amount of data routinelysent to the satellite be kept to a minimum. For most transmissions, thisinformation will involve the location of the container, for example,plus a few additional bytes of status information determined by themission of the particular container and its contents. Thus, the patternrecognition algorithms must convert typically a complex image or otherdata to a few bytes representative of the class of the monitored item orevent.

In some instances, the container must send considerably more data and ata more frequent interval than normal. This will generally happen onlyduring an exceptional situation or event and when the added batterydrain of this activity is justified. In this case, the system willsignal the satellite that an exception situation exists and to prepareto receive additional information.

Many of the sensors on the container and inside the container may alsorequire significant energy and thus should be used sparingly. Forexample, if the container is known to be empty and the doors closed,there is no need to monitor the interior of the container unless thedoors have been reopened. Similarly, if the container is stationary anddoors are closed, then continuously monitoring the interior of thecontainer to determine the presence of cargo is unnecessary. Thus, eachof the sensors can have a program duty cycle that depends on exterior orother events. In some applications either solar power or other source ofpower may be available either intermittently to charge the battery orcontinuously.

If the vehicle such as a container is stationary then usually themonitoring can take place infrequently and the battery is conserved.When the vehicle is in motion then energy is frequently available tocharge the battery and thus more frequent monitoring can take place asthe battery is charged. The technique in known as “energy harvesting”and involves, for example, the use of a piezoelectric material that iscompressed, bent or otherwise flexed thereby creating an electriccurrent that can be used to charge the battery. Other methods includethe use of a magnet and coil where the magnet moves relative to the coilunder forces caused by the motion of the vehicle.

Since the duty cycle of the sensor system may vary considerably, andsince any of the sensors can fail, be sabotaged or otherwise be renderedincapable of performing its intended function either from time,exposure, or intentionally, it is expected that some or all of thesensors will be equipped with a diagnostic capability. The communicationsystem will generally interrogate each sensor or merely expect atransmission from each sensor and if that interrogation or transmissionfails or a diagnostic error occurs, this fact will be communicated tothe appropriate facility. If, for example, someone attempts to cover thelens of a camera so that a theft would not be detected, the mere factthat the lens was covered could be reported, alerting authorities thatsomething unusual was occurring.

As mentioned previously, there are times when the value of the contentsof a container can exceed the value of the tractor, chassis andcontainer itself. Additionally, there are times when the contents of thecontainer can be easily damaged if subjected to unreasonable vibrations,angles, accelerations and shocks. For these situations, an inertialmeasurement unit (IMU) can be used in conjunction with the container tomonitor the accelerations experienced by the container (or the cargo)and to issue a warning if those accelerations are deemed excessiveeither in magnitude, duration, or frequency or where the integrations ofthese accelerations indicate an excessive velocity, angular velocity orangular displacement. Note that for some applications in order tominimize the power expended at the sensor installation, the IMUcorrection calculations based on the GPS can be done at an off sensorlocation such as the receiving station of the satellite information.

If the vehicle operates on a road that has previously been accuratelymapped, to an accuracy of perhaps a few centimeters, then the analysissystem can know the input from the road to the vehicle tires and thus tothe chassis of the trailer. The IMU can also calculate the velocity ofthe trailer. By monitoring the motion of the container when subjected toa known stimulus, the road, the inertial properties of the container andchassis system can be estimated. If these inertial properties are knownthan a safe operating speed limit can be determined such that theprobability of rollover, for example, is kept within reasonable bounds.If the driver exceeds that velocity, then a warning can be issued.Similarly, in some cases, the traction of the trailer wheels on theroadway can be estimated based on the tendency of a trailer to skidsideways. This also can be the basis of issuing a warning to the driverand to notify the contents owner especially if the vehicle is beingoperated in an unsafe manner for the road or weather conditions. Sincethe information system can also know the weather conditions in the areawhere the vehicle is operating, this added information can aid in thesafe driving and safe speed limit determination. In some cases, thevibrations caused by a failing tire can also be determined. For thosecases where radio frequency tire monitors are present, the container canalso monitor the tire pressure and determine when a dangerous situationexists. Finally, the vehicle system can input to the overall system whenthe road is covered with ice or when it encounters a pothole.

Thus, there are many safety related aspects to having sensors mounted ona container and where those sensors can communicate periodically with aLEO or other satellite, or other communication system, and thereafter tothe Internet or directly to the appropriate facility. Some of these relyon an accurate IMU. Although low cost IMUs are generally not veryaccurate, when they are combined using a Kalman filter with the GPSsystem, which is on the container as part of the tracking system, theaccuracy of the IMU can be greatly improved, approaching that ofmilitary grade systems.

The discussion above has concentrated on containers that contain cargowhere presumably this cargo is shipped from one company or organizationto another. This cargo could be automotive parts, animals, furniture,weapons, bulk commodities, machinery, fruits, vegetables, TV sets, orany other commonly shipped product. What has been described above is amonitoring system for tracking this cargo and making measurements toinform the interested parties (owners, law enforcement personnel etc.)of the status of the container, its contents, and the environment. Thisbecomes practical when a satellite system exists such as the Skybitz,for example, LEO or geostationary satellite system coupled with a lowcost low power small GPS receiver and communication device capable ofsending information periodically to the satellite. Once the satellitehas received the position information from the container, for example,this information can be relayed to a computer system wherein the exactlocation of the container can be ascertained. Additionally, if thecontainer has an RFID reader, the location of all packages having anRFID tag that are located within the container can also be ascertained.

The accuracy of this determination is currently now approximately 20meters. However, as now disclosed for the first time, the ionospherecaused errors in GPS signals received by container receiver can bedetermined from a variety of differential GPS systems and thatinformation can be coupled with the information from the container todetermine a precise location of the container to perhaps as accurate asa few centimeters. This calculation can be done at any facility that hasaccess to the relevant DGPS corrections and the container location. Itneed not be done onboard the container. Using accurate digital maps thelocation of the container on the earth can be extremely preciselydetermined. This principle can now be used for other locationdetermining purposes. The data processing facility that receives theinformation from the asset via satellites can also know the DGPScorrections at the asset location and thus can relay to the vehicle itsprecise location.

Although the discussion above has centered on cargo transportation as anillustrative example, at least one of the inventions disclosed herein isnot limited thereto and in fact can be used with any asset whethermovable or fixed where monitoring for any of a variety of reasons isdesired. These reasons include environmental monitoring, for example,where asset damage can occur if the temperature, humidity, or otheratmospheric phenomena exceeds a certain level. Such a device then couldtransmit to the telecommunications system when this exception situationoccurred. It still could transmit to the system periodically, perhapsonce a day, just to indicate that all is OK and that an exceptionalsituation did not occur.

Another example could be the monitoring of a vacation home during themonths when the home is not occupied. Of course, any home could be somonitored even when the occupants leave the home unattended for a party,for example. The monitoring system could determine whether the house ison fire, being burglarized, or whether temperature is dropping to thepoint that pipes could freeze due to a furnace or power failure. Such asystem could be less expensive to install and maintain by a homeowner,for example, than systems supplied by ADT, for example. Monitoring of areal estate location could also be applied to industrial, governmentaland any other similar sites. Any of the sensors includingelectromagnetic, cameras, ultrasound, capacitive, chemical, moisture,radiation, biological, temperature, pressure, radiation, etc. could beattached to such a system which would not require any other electricalconnection either to a power source or to a communication source such asa telephone line which is currently require by ADT, for example. Infact, most currently installed security and fire systems require both aphone and a power connection. If a power source is available, it can beused to recharge the batteries or as primary power.

Of particular importance, this system and techniques can be applied togeneral aviation and the marine community for the monitoring of flightand boat routings. For general aviation, this or a similar system can beused for monitoring the unauthorized approach of planes or boats topublic utilities, government buildings, bridges or any other structureand thereby warn of possible terrorist activities.

Portable versions of this system can also be used to monitor livingobjects such as pets, children, animals, cars, and trucks, or any otherasset. What is disclosed herein therefore is a truly general assetmonitoring system where the type of monitoring is only limited byrequirement that the sensors operate under low power and the device doesnot require connections to a power source, other than the internalbattery, or a wired source of communication. The communication link isgenerally expected to be via a transmitter and a LEO, geostationary orother satellite, however, it need not be the case and communication canbe by cell phone, an ad hoc peer-to-peer network, IEEE 801.11,Bluetooth, or any other wireless system. Thus, using the teachings of atleast one of the inventions disclosed herein, any asset can be monitoredby any of a large variety of sensors and the information communicatedwireless to another location which can be a central station, apeer-to-peer network, a link to the owners location, or, preferably, tothe Internet.

Additional areas where the principles of the invention can be used formonitoring other objects include the monitoring of electric fieldsaround wires to know when the wires have failed or been cut, themonitoring of vibrations in train rails to know that a train is comingand to enable tracking of the path of trains, the monitoring ofvibrations in a road to know that a vehicle is passing, the monitoringof temperature and/or humidity of a road to signal freezing conditionsso that a warning could be posted to passing motorists about theconditions of the road, the monitoring of vibrations or flow in a oilpipe to know if the flow of oil has stopped or being diverted so that adetermination may be made if the oil is being stolen, the monitoring ofinfrared or low power (MIR) radar signal monitoring for perimetersecurity, the monitoring of animals and/or traffic to warn animals thata vehicle is approaching to eliminate car to animal accidents and themonitoring of fluid levels in tanks or reservoirs. It is also possibleto monitor grain levels in storage bins, pressure in tanks, chemicals inwater or air that could signal a terrorist attack, a pollution spill orthe like, carbon monoxide in a garage or tunnel, temperature orvibration of remote equipment as a diagnostic of pending system failure,smoke and fire detectors and radiation. In each case, one or moresensors is provided designed to perform the appropriate, desiredsensing, measuring or detecting function and a communications unit iscoupled to the sensor(s) to enable transmission of the informationobtained by the sensor(s). A processor can be provided to control thesensing function, i.e., to enable only periodic sensing or sensingconditioned on external or internal events. For each of these and manyother applications, a signal can be sent to a satellite or othertelematics system to send important information to a need-to-knowperson, monitoring computer program, the Internet etc.

Three other applications of at least one of the inventions disclosedherein need particular mention. Periodically, a boat or barge impactswith the structure of a bridge resulting in the collapse of a road,railroad or highway and usually multiple fatalities. Usually such anevent can be sensed prior to the collapse of the structure by monitoringthe accelerations, vibrations, displacement, or stresses in thestructural members. When such an event is sensed, a message can be sentto a satellite and/or forwarded to the Internet, and thus to theauthorities and to a warning sign or signal that has been placed at alocation preceding entry onto the bridge. Alternately, the sensingdevice can send a signal directly to the relevant sign either inaddition or instead of to a satellite.

Sometimes the movement of a potentially hazardous cargo in itself is notsignificantly unless multiple such movements follow a pattern. Forexample, the shipment of moderate amounts of explosives forwarded to asingle location could signify an attack by terrorists. By comparing themotion of containers of hazardous materials and searching for patterns,perhaps using neural networks, fuzzy logic and the like, suchconcentrations of hazardous material can be forecasted prior to theoccurrence of a disastrous event. This information can be gleaned fromthe total picture of movements of containers throughout a local, stateor national area. Similarly, the movement of fuel oil and fertilizer byitself is usually not noteworthy but in combination using differentvehicles can signal a potential terrorist attack.

Many automobile owners subscribe to a telematics service such asOnStar®. The majority of these owners when queried say that theysubscribe so that if they have an accident and the airbag deploys, theEMS personnel will be promptly alerted. This is the most commonlydesired feature by such owners. A second highly desired feature relatesto car theft. If a vehicle is stolen, the telematics services can trackthat vehicle and inform the authorities as to its whereabouts. A thirdhighly desired feature is a method for calling for assistance in anyemergency such as the vehicle becomes stalled, is hijacked, runs off theroad into a snow bank or other similar event. The biggest negativefeature of the telematics services such as OnStar® is the high monthlycost of the service.

The invention described here can provide the three above-mentionedhighly desired services without requiring a high monthly fee. A simpledevice that communicates to a satellite or other telematics system canbe provided, as described above, that operates either on its own batteryand/or by connecting to the cigarette lighter or similar power source.The device can be provided with a microphone and neural networkalgorithm that has been trained to recognize the noise signature of anairbag deployment or the information that a crash transpired can beobtained from an accelerometer. Thus, if the vehicle is in an accident,the EMS authorities can be immediately notified of the crash along withthe precise location of the vehicle. Similarly, if the vehicle isstolen, its exact whereabouts can be determined through an Internetconnection, for example. Finally, a discrete button placed in thevehicle can send a panic signal to the authorities via a telematicssystem. Thus, instead of a high monthly charge, the vehicle owner wouldonly be charged for each individual transmission, which can be as low as$0.20 or a small surcharge can be added to the price of the device tocover such costs through averaging over many users. Such a system can bereadily retrofitted to existing vehicles providing most of advantages ofthe OnStar® system, for example, at a very small fraction of its cost.The system can reside in a “sleep” mode for many years until some eventwakes it up. In the sleep mode, only a few microamperes of current aredrawn and the battery can last the life of the vehicle. A wake-up can beachieved when the airbag fires and the microphone emits a current.Similarly, a piezo-generator can be used to wake up the system based onthe movement of a mass or diaphragm displacing a piezoelectric devicewhich then outputs some electrical energy that can be sensed by thesystem electronics. Similarly, the system can be caused to wake up by aclock or the reception of a proper code from an antenna. Such agenerator can also be used to charge the system battery extending itsuseful life. Such an OnStar®-like system can be manufactured forapproximately $100, depending on production volume and features.

The invention described above can be used in any of its forms to monitorfluids. For example, sensors can be provided to monitor fuel or oilreservoirs, tanks or pipelines and spills. Sensors can be arranged in,on, within, in connection with or proximate a reservoir, tank orpipeline and powered in the manner discussed above, and coupled to acommunication system as discussed above. When a property ofcharacteristic of the environment is detected by the sensor, forexample, detection of a fluid where none is supposed to be (which couldbe indicative of a spill), the sensor can trigger a communication systemto transmit information about the detection of the fluid to a remotesite which could send response personnel, i.e., clean-up personnel. Thesensors can be designed to detect any variables which could providemeaningful information, such as a flow sensor which could detectvariations in flow, or a chemical sensor which could detect the presenceof a harmful chemical, biological agent or a radiation sensor whichcould detect the presence of radioactivity. Appropriate action could betaken in response to the detection of chemicals or radioactivity.

Remote water monitoring is also contemplated in the invention sincewater supplies are potentially subject to sabotage, e.g., by theplacement of harmful chemicals or biological agents in the water supply.In this case, sensors would be arranged in, on, within, in connectionwith or proximate water reservoirs, tanks or pipelines and powered inthe manner discussed above, and coupled to a communication system asdiscussed above. Information provided by the sensors is periodicallycommunicated to a remote site at which it is monitored. If a sensordetects the presence of a harmful chemical or agent, appropriate actioncan be taken to stop the flow of water from the reservoir to municipalsystems.

Even the pollution of the ocean and other large bodies of waterespecially in the vicinity of a shore can now be monitored for oilspills and other occurrences.

Similarly, remote air monitoring is contemplated within the scope of theinvention. Sensors are arranged at sites to monitor the air and detect,for example, the presence of radioactivity and bacteria. The sensors cansend the information to a communication system which transmits theinformation to a remote site for monitoring. Detection of aberrations inthe information from the sensors can lead to initiation of anappropriate response, e.g., evacuation in the event of radioactivitydetection.

The monitoring of forests for fires is also a possibility with thepresent invention, although satellite imaging systems are the preferredapproach.

An additional application is the monitoring of borders such as the onebetween the United States and Mexico. Sensors can be placed periodicallyalong such a border at least partially in the ground that are sensitiveto vibrations, infrared radiation, sound or other disturbances. Suchsensor systems can also contain a pattern recognition system that istrained to recognize characteristic signals indicating the passing of aperson or vehicle. When such a disturbance occurs, the system can“wake-up” and receive and analyze the signal and if it is recognized, atransmission to a communication system can occur. Since the transmissionwould also contain either a location or an identification number of thedevice, the authorities would know where the border infraction wasoccurring.

Above, the discussion of the invention has included the use of alocation determining signal such as from a GPS or other locationdetermining system such as the use of time of arrival calculations fromreceptions from a plurality of cell phone antennas. If the device islocated in a fixed place where it is unlikely to move, then the locationof that place need only be determined once when the sensor system is putin place. The identification number of the device can then be associatedwith the device location in a database, for example. Thereafter, justthe transmission of the device ID can be used to positively identify thedevice as well as its location. Even for movable cargo containers, forexample, if the container has not moved since the last transmission,there is no need to expend energy receiving and processing the GPS orother location determining signals. If the device merely responds withits identification number, the receiving facility knows its location.The GPS processing circuitry can be reactivated if sensors on the assetdetermine that the asset has moved.

Once the satellite or other communication system has received a messagefrom the sensor system of at least one of the inventions disclosedherein, it can either store the information into a database or, morecommonly, it can retransmit or make available the data usually on theInternet where subscribers can retrieve the data and use it for theirown purposes. Since such sensor systems are novel to at least one of theinventions disclosed herein, the transmission of the data via theInternet and the business model of providing such data to subscribingcustomers either on an as-needed bases or on a push basis where thecustomer receives an alert is also novel. Thus, for example, a customermay receive an urgent automatically-generated e-mail message or even apop-up message on a particular screen that there is a problem with aparticular asset that needs immediate attention. The customer can be asubscriber, a law enforcement facility, or an emergency servicesfacility, among others.

An additional dimension exists with the use of the Skybitz system, forexample, where the asset mounted device has further wirelesscommunications with other devices in or on the asset. The fact thatcertain tagged items within or on the assets can be verified if a localarea network exists between the Skybitz device and other objects.Perhaps it is desired to check that a particular piece of test equipmentis located within an asset. Further perhaps it is desired to determinethat the piece of equipment is operating or operating within certainparameter ranges, or has a particular temperature etc. Perhaps it isdesired to determine whether a particular set of keys are in a key boxwherein the keys are fitted with an RFID tag and the box with a readerand method of communicating with the Skybitz device. The possibilitiesare endless for determining the presence or operating parameters of acomponent of occupying item of a remote asset and to periodicallycommunicate this information to an internet site, for example, using alow power asset monitoring system such as the Skybitz system.

The Skybitz or similar system can be used with cell phones to provide alocation determination in satisfaction to US Federal regulations. Theadvantage of this use of Skybitz is that it is available world wide anddoes not require special equipment at the cell phone station. This alsopermits an owner of a cell phone to determine its whereabouts for caseswhere it was lost or stolen. A similar system can be added to PDAs orother CD players, radios, or any other electronic device that a humanmay carry. Even non electronic devices such as car keys could beoutfitted with a Skybitz type device. It is unlikely that such a devicewould have a 10 year life but many of them have batteries that areperiodically charged and the others could have a very low duty cyclesuch that they last up to one year without replacement of the batteryand then inform the owner that the battery is low. This informationprocess could even involve the sending of an email message to theowner's email stating the location of the device and the fact that thebattery needs replacement.

Some of the inventions herein relate generally to telematics and thetransmission of information from a vehicle to one or more remote siteswhich can react to the position or status of the vehicle and/oroccupant(s) or contents therein.

Initially, sensing of the occupancy of the vehicle and the optionaltransmission of this information, which may include images, to remotelocations will be discussed. This entails obtaining information fromvarious sensors about the occupants in the passenger compartment of thevehicle, for example, e.g., the number of occupants, their type andtheir motion, if any. Then, the concept of a low cost automatic crashnotification system will be discussed. Next, a diversion intoimprovements in cell phones will be discussed followed by a discussionof trapped children and how telematics can help save their lives.Finally, the use of telematics with non-automotive vehicles will roundout this section.

The use of telematics is included with a discussion of general vehiclediagnostic methods with the diagnosis being transmittable via acommunications device to the remote locations is discussed in the parent'363 application. The diagnostics section includes an extensivediscussion of various sensors for use on the vehicle to sense differentoperating parameters and conditions of the vehicle is provided. All ofthe sensors discussed herein can be coupled to a communications deviceenabling transmission of data, signals and/or images to the remotelocations, and reception of the same from the remote locations. Manytransmission modes exist including cellular phone systems, satellitecommunications and the Internet. The Internet systems can be broken intotwo types, those that are available only at particular “hot-spots” andthe use of ubiquitous internet. The use of ubiquitous internet isbelieved to be unique to the inventions herein as the inventor may havebeen the first to recognize that ubiquitous internet would becomeavailable and can be counted on to provide the sole system forcommunication from various vehicles including automobiles, trucks andtruck trailers, storage tanks and shipping containers replacing allother communication systems. Their vision is now being realized throughsuch systems as WiMAX.

The cellular phone system, ubiquitous internet, or other telematicscommunication device, is shown schematically in FIG. 2 of the parent'363 application and outputs to an antenna. The phone system ortelematics communication device 34 can be coupled to the vehicleinterior monitoring system in accordance with any of the embodimentsdisclosed herein and serves to establish a communications channel withone or more remote assistance facilities, such as an EMS facility ordispatch facility from which emergency response personnel aredispatched. The telematics system can also be a satellite-based systemsuch as provided by Skybitz.

In the event of an accident, the electronic system associated with thetelematics system interrogates the various interior monitoring systemmemories in processor 20 and can arrive at a count of the number ofoccupants in the vehicle, if each seat is monitored, and, in moresophisticated systems, even makes a determination as to whether eachoccupant was wearing a seatbelt and if he or she is moving after theaccident, and/or the health state of one or more of the occupants asdescribed above, for example. The telematics communication system thenautomatically notifies an EMS operator (such as 911, OnStar® orequivalent) and the information obtained from the interior monitoringsystems is forwarded so that a determination can be made as to thenumber of ambulances and other equipment to send to the accident site.Vehicles having the capability of notifying EMS in the event one or moreairbags deployed are now in service but are not believed to use any ofthe innovative interior monitoring systems described herein. Suchvehicles will also have a system, such as the global positioning system,which permits the vehicle to determine its location and to forward thisinformation to the EMS operator.

In relation to this aspect, see the discussion above of the schematicshown in FIG. 61 of the parent '363 application.

Once an occupying item has been located in a vehicle, or any objectoutside of the vehicle, the identification or categorization informationalong with an image, including an IR or multispectral image, or icon ofthe object can be sent via a telematics channel to a remote location. Apassing vehicle, for example, can send a picture of an accident or asystem in a vehicle that has had an accident can send an image of theoccupant(s) of the vehicle to aid in injury assessment by the EMS team.

Although in most if not all of the embodiments described above, it hasbeen assumed that the transmission of images or other data from thevehicle to the EMS or other off-vehicle (remote) site is initiated bythe vehicle, this may not always be the case and in some embodiments,provision is made for the off-vehicle site to initiate the acquisitionand/or transmission of data including images from the vehicle. Thus, forexample, once an EMS operator knows that there has been an accident, heor she can send a command to the vehicle to control components in thevehicle to cause the components send images and other data so that thesituation can be monitored by the operator or other person. Thecapability to receive and initiate such transmissions can also beprovided in an emergency vehicle such as a police car or ambulance. Inthis manner, for a stolen vehicle situation, the police officer, forexample, can continue to monitor the interior of the stolen vehicle.

FIG. 26 shows a schematic of the integration of the occupant sensingwith a telematics link and the vehicle diagnosis with a telematics link.As envisioned, the occupant sensing system 600 includes those componentswhich determine the presence, position, health state, and otherinformation relating to the occupants, for example the transducersdiscussed with reference to FIGS. 1, 2 and 61 of the parent '363application and the SAW device discussed with reference to FIG. 62 ofthe '363 application. Information relating to the occupants includesinformation as to what the driver is doing, talking on the phone,communicating with OnStar® or other route guidance, listening to theradio, sleeping, drunk, drugged, having a heart attack The occupantsensing system may also be any of those systems and apparatus describedin the current assignee's patents and patent applications or any othercomparable occupant sensing system which performs any or all of the samefunctions as they relate to occupant sensing. Examples of sensors whichmight be installed on a vehicle and constitute the occupant sensingsystem include heartbeat sensors, motion sensors, weight sensors,microphones and optical sensors.

A crash sensor system 591 is provided and determines when the vehicleexperiences a crash. This crash sensor may be part of the occupantrestraint system or independent from it. Crash sensor system 591 mayinclude any type of crash sensors, including one or more crash sensorsof the same or different types.

Vehicle sensors 592 include sensors which detect the operatingconditions of the vehicle such as those sensors discussed with referenceto FIGS. 136-141 of the '881 application. Also included are tire sensorssuch as disclosed in U.S. Pat. No. 6,662,642. Other examples includevelocity and acceleration sensors, and angle and angular rate pitch,roll and yaw sensors. Of particular importance are sensors that tellwhat the car is doing: speed, skidding, sliding, location, communicatingwith other cars or the infrastructure, etc.

Environment sensors 593 includes sensors which provide data to theoperating environment of the vehicle, e.g., the inside and outsidetemperatures, the time of day, the location of the sun and lights, thelocations of other vehicles, rain, snow, sleet, visibility (fog),general road condition information, pot holes, ice, snow cover, roadvisibility, assessment of traffic, video pictures of an accident, etc.Possible sensors include optical sensors which obtain images of theenvironment surrounding the vehicle, blind spot detectors which providesdata on the blind spot of the driver, automatic cruise control sensorsthat can provide images of vehicles in front of the host vehicle,various radar devices which provide the position of other vehicles andobjects relative to the subject vehicle.

The occupant sensing system 600, crash sensors 591, vehicle sensors 592,environment sensors 593 and all other sensors listed herein can becoupled to a communications device 594 which may contain a memory unitand appropriate electrical hardware to communicate with the sensors,process data from the sensors, and transmit data from the sensors. Thememory unit would be useful to store data from the sensors, updatedperiodically, so that such information could be transmitted at set timeintervals.

The communications device 594 can be designed to transmit information toany number of different types of facilities. For example, thecommunications device 594 would be designed to transmit information toan emergency response facility 595 in the event of an accident involvingthe vehicle. The transmission of the information could be triggered by asignal from a crash sensor 591 that the vehicle was experiencing a crashor experienced a crash. The information transmitted could come from theoccupant sensing system 600 so that the emergency response could betailored to the status of the occupants. For example, if the vehicle wasdetermined to have ten occupants, multiple ambulances might be sent.Also, if the occupants are determined not be breathing, then a higherpriority call with living survivors might receive assistance first. Assuch, the information from the occupant sensing system 600 would be usedto prioritize the duties of the emergency response personnel.

Information from the vehicle sensors 592 and environment sensors 593 canalso be transmitted to law enforcement authorities 597 in the event ofan accident so that the cause(s) of the accident could be determined.Such information can also include information from the occupant sensingsystem 600, which might reveal that the driver was talking on the phone,putting on make-up, or another distracting activity, information fromthe vehicle sensors 592 which might reveal a problem with the vehicle,and information from the environment sensors 593 which might reveal theexistence of slippery roads, dense fog and the like.

Information from the occupant sensing system 600, vehicle sensors 592and environment sensors 593 can also be transmitted to the vehiclemanufacturer 598 in the event of an accident so that a determination canbe made as to whether failure of a component of the vehicle caused orcontributed to the cause of the accident. For example, the vehiclesensors might determine that the tire pressure was too low so thatadvice can be disseminated to avoid maintaining the tire pressure toolow in order to avoid an accident. Information from the vehicle sensors592 relating to component failure could be transmitted to adealer/repair facility 596 which could schedule maintenance to correctthe problem.

The communications device 594 can be designed to transmit particularinformation to each site, i.e., only information important to beconsidered by the personnel at that site. For example, the emergencyresponse personnel have no need for the fact that the tire pressure wastoo low but such information is important to the law enforcementauthorities 597 (for the possible purpose of issuing a recall of thetire and/or vehicle) and the vehicle manufacturer 598.

In one exemplifying use of the system shown in FIG. 26, the operator atthe remote facility 595 could be notified when the vehicle experiences acrash, as detected by the crash sensor system 591 and transmitted to theremote facility 595 via the communications device 594. In this case, ifthe vehicle occupants are unable to, or do not, initiate communicationswith the remote facility 595, the operator would be able to receiveinformation from the occupant sensing system 600, as well as the vehiclesensors 592 and environmental sensors 593. The operator could thendirect the appropriate emergency response personnel to the vehicle. Thecommunications device 594 could thus be designed to automaticallyestablish the communications channel with the remote facility when thecrash sensor system 591 determines that the vehicle has experienced acrash.

The communications device 594 can be a cellular phone, OnStar® or othersubscriber-based telematics system, a peer-to-peer vehicle communicationsystem that eventually communicates to the infrastructure and then,perhaps, to the Internet with e-mail to the dealer, manufacturer,vehicle owner, law enforcement authorities or others. It can also be avehicle to LEO or Geostationary satellite system such as Skybitz whichcan then forward the information to the appropriate facility eitherdirectly or through the Internet. It can also be directly to aubiquitous internet system such as WiMAX.

The communication may need to be secret so as not to violate the privacyof the occupants and thus encrypted communication may in many cases berequired. Other innovations described herein include the transmission ofany video data from a vehicle to another vehicle or to a facility remotefrom the vehicle by any means such as a telematics communication systemsuch as OnStar®, a cellular phone system, a communication via GEO,geocentric or other satellite system and any communication thatcommunicates the results of a pattern recognition system analysis. Also,any communication from a vehicle that combines sensor information withlocation information is anticipated by at least one of the inventionsdisclosed herein.

When optical sensors are provided as part of the occupant sensing system600, video conferencing becomes a possibility, whether or not thevehicle experiences a crash. That is, the occupants of the vehicle canengage in a video conference with people at another location 599 viaestablishment of a communications channel by the communications device594.

The vehicle diagnostic system described above using a telematics linkcan transmit information from any type of sensors on the vehicle.

A system for notifying remote personnel, e.g., emergency responsepersonnel, of an accident is described herein.

Using the any of the various communication systems described above, anautomatic crash notification system can be built. The crash can besensed by the airbag crash or rollover sensors or the deployment of theairbag event can be sensed to trigger the communication of the event.The system can be powered by the vehicle power or a battery can be usedthat has a very long life since the system would draw little currentuntil the event. An advantage of a self-powered system is that it can bemore easily retrofitted to existing vehicles. Additionally, aself-powered system would still operate on the loss of vehicle powerwhich can happen during a crash. A small energy harvesting unit based onvibrations or light can be incorporated to overcome battery loss due toleakage and maintain the battery in a charged state for the life of thevehicle. This self-contained system can use a microphone, for example,to sense airbag deployment and thus the only wiring required would be tothe communication system which also could be contained within the unit.In some cases, the unit can be on the vehicle safety bus where it couldderive both power and crash information. In this latter case, a backuppower supply in the form of a capacitor can be provided. Thecommunication system can be any of those mentioned above including asatellite based system such as provided by SkyBitz, Inc., the cellularphone system or, preferably, a ubiquitous internet system such as WiMAX.Such a ubiquitous system is not yet in service but the inventor believesthat the arguments for such a system are overwhelming and thus it willoccur probably in time for the deployment of a universal automatic crashnotification system as described herein.

Any or all of the information obtained from occupancy and other onboardsensors can be part of the information sent to the remote location viathe communication or telematics system.

When the driver of a vehicle is using a cellular phone, the phonemicrophone frequently picks up other noise in the vehicle making itdifficult for the other party to hear what is being said. This noise canbe reduced if a directional microphone is used and directed toward themouth of the driver. This is difficult to do since the position ofdriver's mouth varies significantly depending on such things as the sizeand seating position of the driver. By using the vehicle interioridentification and monitoring system of at least one of the inventionsdisclosed herein, and through appropriate pattern recognitiontechniques, the location of the driver's head can be determined withsufficient accuracy even with ultrasonics to permit a directionalmicrophone assembly to be sensitized to the direction of the mouth ofthe driver resulting in a clear reception of his voice. The use ofdirectional speakers in a similar manner also improves the telephonesystem performance. In the extreme case of directionality, thetechniques of hypersonic sound can be used. Such a system can also beused to permit effortless conversations between occupants of the frontand rear seats. Such a system is shown in FIG. 40 of the parent '363application, which is a system similar to that of FIG. 2 only usingthree ultrasonic transducers to determine the location of the driver'shead and control the pointing direction of a microphone. Speaker isshown connected schematically to the phone system 34 completing thesystem.

One transducer can be placed high in the A-pillar, another transducer onthe headliner and yet another transducer on the IP. Other locations arepossible as discussed above. The three transducers are placed high inthe vehicle passenger compartment so that the first returned signal isfrom the head. Temporal filtering is used to eliminate signals that arereflections from beyond the head and the determination of the headcenter location is then found by the approximate centroid of thehead-returned signal. That is, once the location of the return signalcentroid is found from the three received signals from transducers, thedistance to that point is known for each of the transducers based on thetime it takes the signal to travel from the head to each transducer. Inthis manner, by using the three transducers, all of which send andreceive, plus an algorithm for finding the coordinates of the headcenter, using a processor, and through the use of known relationshipsbetween the location of the mouth and the head center, an estimate ofthe mouth location, and the ear locations, can be determined within acircle having a diameter of about five inches (13 cm). This issufficiently accurate for a directional microphone to cover the mouthwhile excluding the majority of unwanted noise. Camera-based systems canbe used to more accurately locate parts of the body such as the head.

The placement of multiple imagers in the vehicle, the use of a plasticelectronics-based display plus telematics permits the occupants of thevehicle to engage in a video conference if desired. Until autonomousvehicles appear, it would be best if the driver did not participate.

The transmission of data obtained from imagers, or other transducers, toanother location, requiring the processing of the information, usingneural networks for example, to a remote location is an importantfeature of some of the inventions disclosed herein. This capability canpermit an owner of a cargo container, storage tank or truck trailer toobtain a picture of the interior of the vehicle at any time viatelematics. When coupled with occupant sensing, the driver of a vehiclecan be recognized and the result sent by telematics for authorization tominimize the theft or unauthorized operation of a vehicle. Therecognition of the driver can either be performed on the vehicle or animage of the driver can be sent to a remote location for recognition atthat location.

Generally monitoring of containers, trailers, chassis etc. isaccomplished through telecommunications primarily with LEO orgeostationary satellites or through terrestrial-based communicationsystems. These systems are commercially available and will not bediscussed here. Expected future systems include communication betweenthe container and the infrastructure to indicate to the monitoringauthorities that a container with a particular identification number ispassing a particular terrestrial point. If this is expected, then noaction would be taken. The container identification number can be partof a national database that contains information as to the contents ofthe container. Thus, for example, if a container containing hazardousmaterials approaches a bridge or tunnel that forbids such hazardousmaterials from passing over the bridge or through the tunnel, then anemergency situation can be signaled and preventive action taken.

It is expected that monitoring of the transportation of cargo containerswill dramatically increase as the efforts to reduce terrorist activitiesalso increase. If every container that passes within the borders of theUnited States has an identification number and that number is in adatabase that provides the contents of that container, then the use ofshipping containers by terrorists or criminals should gradually beeliminated. If these containers are carefully monitored by satellite oranother communication system that indicates any unusual activity of acontainer, an immediate investigation can result and then the cargotransportation system will gradually approach perfection whereterrorists or criminals are denied this means of transporting materialinto and within the United States. If any container is found containingcontraband material, then the entire history of how that containerentered the United States can be checked to determine the source of thefailure. If the failure is found to have occurred at a loading portoutside of the United States, then sanctions can be imposed on the hostcountry that could have serious effects on that country's ability totrade worldwide. Just the threat of such an action would be asignificant deterrent. Thus, the use of containers to transporthazardous materials or weapons of mass destruction as well as people,narcotics, or other contraband and can be effectively eliminated throughthe use of the container monitoring system of at least one of theinventions disclosed herein.

Prior to the entry of a container ship into a harbor, a Coast Guard boatfrom the U.S. Customs Service can approach the container vessel and scanall of the containers thereon to be sure that all such containers areregistered and tracked including their contents. Where containerscontain dangerous material legally, the seals on those containers can becarefully investigated prior to the ship entering U.S. waters.Obviously, many other security precautions can now be conceived once theability to track all containers and their contents has been achievedaccording to the teachings of at least one of the inventions disclosedherein.

Containers that enter the United States through land ports of entry canalso be interrogated in a similar fashion. As long as the shipper isknown and reputable and the container contents are in the database,which would probably be accessible over the Internet, is properlyupdated, then all containers will be effectively monitored that enterthe United States with the penalty of an error resulting in thedisenfranchisement of the shipper, and perhaps sanctions against thecountry, which for most reputable shippers or shipping companies wouldbe a severe penalty sufficient to cause such shippers or shippingcompanies to take appropriate action to assure the integrity of theshipping containers. Intelligent selected random inspections guided bythe container history would still take place.

Although satellite communication is preferred, communication using cellphones and infrastructure devices placed at appropriate locations alongroadways are also possible. Eventually there will be a network linkingall vehicles on the highways in a peer-to-peer arrangement (perhapsusing Bluetooth, IEEE 802.11 (WI-FI), Wi-Mobile or other local, mesh orad-hoc network) at which time information relative to container contentsetc. can be communicated to the Internet or elsewhere through thispeer-to-peer network. It is expected that a pseudo-noise-based orsimilar communication system such as a code division multiple access(CDMA) system, wherein the identifying code of a vehicle is derived fromthe vehicle's GPS determined location, will be the technology of choicefor this peer-to-peer vehicle network. It is expected that this networkwill be able to communicate such information to the Internet (withproper security precautions including encryption where necessary ordesired) and that all of the important information relative to thecontents of moving containers throughout the United States will beavailable on the Internet on a need-to-know basis. Thus, law enforcementagencies can maintain computer programs that will monitor the contentsof containers using information available from the Internet. Similarly,shippers and receivers can monitor the status of their shipments througha connection onto the Internet. Thus, the existence of the Internet orequivalent can be important to the monitoring system described herein.The implementation of a ubiquitous internet service would greatlyfacilitate this type of container tracking through the infrastructureand information transfer into appropriate databases.

Referring now to FIG. 25, an alternate method of implementing theinvention is to make use of a cell phone or PDA. Cell phones that arenow sold contain a GPS-based location system as do many PDAs. Such asystem along with minimal additional apparatus can be used to practicethe teachings disclosed herein. In this case, the cell phone, PDA orsimilar portable device 100 could be mounted through a snap-inattachment system 102, for example, wherein the portable device 100 isfirmly attached to the vehicle 104. The vehicle monitoring device 106can at that point, for example, obtain an ID number from the containerthrough a variety of methods such as a RFID, SAW or hardwired basedsystem. It can also connect to a satellite antenna that would permit thedevice to communicate to a LEO or GEO satellite system, such as Skybitzas described above. Since the portable device 100 would only operate ona low duty cycle, the battery should last for many days or perhapslonger. Of course, if it is connected to the vehicle power system, or toan energy harvesting system 110, its life could be indefinite. Whenpower is waning, this fact can be sent to the satellite or cell phonesystem to alert the appropriate personnel at a remote facility 108.Since a cell phone 100 contains a microphone, it could be trained, usingan appropriate pattern recognition system, to recognize the sound of anaccident or the deployment of an airbag or similar event. It thusbecomes a very low cost OnStar® type telematics system. The cell phoneor PDA could be programmed to transmit a signal when it detects any ofthese noises, i.e., to a remote monitoring facility or emergencyresponse facility 108. The remote facility 108 could then direct aid tothe vehicle 104 once the position of the vehicle 104 is determined.

The cell phone or PDA 100 could also be used to provide information toenable an off-site computer, e.g., at a remote location, to determinethe position of the cell phone and thus the vehicle 104 or other assetin which it is arranged. The cell phone would provide data aboutreception of signals, e.g., from satellites and/or other wirelessbeacons, and this data would be transmitted via the communicationsfunction of the cell phone or PDA 100 to the remote site. At the remotesite, the position or location of the cell phone or PDA 100 (and vehicle104) would be determined by performing, e.g., DGPS calculations.

As an alternative to using a satellite network, the cell phone networkcan be used in essentially the same manner when a cell phone signal isavailable. All of the sensors disclosed herein can either beincorporated into the portable device or placed on the vehicle andconnected to the portable device when the device is attached to thevehicle. This system has a key advantage of avoiding obsolescence. Withtechnology rapidly changing, the portable device can be exchanged for alater model or upgraded as needed or desired, keeping the overall systemat the highest technical state. Existing telematics systems such asOnStar® can of course also be used with this system.

Importantly, an automatic emergency notification system can now be madeavailable to all owners of appropriately configured cell phones, PDAs,or other similar portable devices that can operate on a very low costbasis without the need for a monthly subscription since they can bedesigned to operate only on an exception basis. Owners would pay only asthey use the service. Stolen vehicle location, automatic notification inthe event of a crash even with the transmission of a picture forcamera-equipped devices is now possible. Automatic door unlocking canalso be done by the device since it could transmit a signal to thevehicle, in a similar fashion as a keyless entry system, from eitherinside or outside the vehicle. The phone can be equipped with abiometric identification system such as fingerprint, voice print, facialor iris recognition etc. thereby giving that capability to vehicles. Thedevice can thus become the general key to the vehicle or house, and caneven open the garage door etc. If the cell phone is lost, itswhereabouts can be instantly found since it has a GPS receiver and knowswhere it is. If it is stolen, it will become inoperable without thebiometric identification from the owner.

Applying this embodiment of the invention, the cell phone or PDA can beused as an environment monitoring system for monitoring the environmentin the vehicle, e.g., in the passenger compartment or interior space ofa container. It could check for chemicals in the air in the passengercompartment or container. An energy harvesting system may be arranged inconnection with the cell phone or PDA to generate energy to power thecell phone or PDA, or various sensors associated therewith, duringmovement of the vehicle.

Referring now to FIG. 25A, an alternate method of implementing theinvention is to make use of a cell phone or PDA to monitor the personcarrying the cell phone or PDA. In this case, the cell phone, PDA orsimilar portable device 100A is carried by the person 104A, for example,in their pocket, using a clip or in a holster or other carryingimplement 102A. Since a cell phone, PDA or other similar portable device100A typically contains a microphone, it could be trained, using anappropriate pattern recognition system, to recognize the sound of areportable incident about the person, e.g., the person falling, theperson calling for help. It thus becomes a very low cost “emergencyalert” type system. The cell phone or PDA could be programmed totransmit a signal when it detects any of these incidents or noises,i.e., to a remote monitoring facility or emergency response facility108A. The remote facility 108A could then direct aid to the person 104Aonce the position of the cell phone 100A is determined. Also, the cellphone, PDA or other similar portable device 100A may be programmed totake a picture when a reportable incident or noise is detected since thepicture may provide information about the incident or the source of thenoise.

It is important that the information obtained about the person 104A orthe environment around the person 104A is not obtained by interactionwith the person, i.e., the person does not manually enter theinformation using an input device such as a keyboard or manually take apicture of the environment. Rather, the portable device 100A is providedwith one or more sensors 112A which automatically sense, detect ormeasure a property about the person, e.g., temperature, and/or theenvironment around the person, e.g., radioactivity level, and dependingon the detection or measurement, transmit data to the remote facility108A which receives and reacts to the information provided by thesensor(s) 112A, if desired and/or warranted. The thresholds of thesensed, detected or measured property to require a transmission may bevaried and adjusted as desired, depending for example, on the personand/or on the environment.

The cell phone, PDA or other similar portable device 100A could also beused to provide information to enable an off-site computer, e.g., at theremote facility 108A, to determine the position of the cell phone andthus the person 104A or vehicle, building or other structure in whichthe person is located it is arranged. The cell phone would provide dataabout reception of signals, e.g., from satellites and/or other wirelessbeacons, and this data would be transmitted via the communicationsfunction of the cell phone, PDA or other similar portable device 100A tothe remote site. At the remote site, the position or location of thecell phone, PDA or similar portable device 100A (and person 104A) wouldbe determined by performing, e.g., DGPS calculations. For example, theportable device 100A may include a locating system arranged to obtainDGPS signals which are transmitted by a communications portion of theportable device 100A to the remote facility 108A to enable the locationof the portable device 100A to be determined from the DGPS signals atthe remote facility 108A.

As an alternative to using a satellite network, the cell phone networkcan be used in essentially the same manner when a cell phone signal isavailable. All of the sensors disclosed herein, e.g., a chemical sensor,can be incorporated into the portable device 100A and connected to theportable device when the device is carried by the person 104A. Thus, ifthe portable device 100A is provided with a radiation sensor, it canenable remote monitoring of the person's exposure to radiation.

The information provided by the portable device 100A, e.g., cell phoneor PDA may be information about a person carrying the cell phone or PDA,derived from contact or proximity of the person to the sensor of thecell phone or PDA. A non-exclusive lists of sensors that may be arrangedin association with the cell phone or PDA include one or more of atemperature sensor, radiation sensor, optical sensor, flow sensor,current sensor, voltage sensor, magnetic field sensor, electric fieldsensor, force sensor, charge sensor, viscosity sensor, density sensor,electrical resistance sensor, electrical impedance sensor, electricalcapacitance sensor, electrical inductance sensor, humidity sensor,chemical sensor, biochemical sensor, biological sensor, accelerationsensor, velocity sensors, displacement sensor, location sensor,vibration sensor, acoustic sensor and pressure sensor.

In one implementation, the portable device 100A includes a processorwhich analyzes the information obtained by the sensor(s) 112A todetermine whether the obtained information requires a transmission tothe remote facility 108A and a communications portion arranged totransmit the obtained information or a signal representative thereofwhen the processor determines that the obtained information requiressuch a transmission. The processor and communications portion may beexisting components of the portable device 100A, i.e., existingcomponents of a cell phone or PDA which are programmed in accordancewith the teachings herein. When a microphone is one of the sensors 112A,it receives sounds which are analyzed by the processor and possiblyrecognized by the processor, i.e., through training, to determinewhether the received sounds are indicative of an accident or otherreportable incident. In this case, the processor transmit an accidentindication signal to the remote facility 108A via the communicationsportion, e.g., only when the sounds of an accident is recognized. Moregenerally, the processor analyzes the obtained information from eachsensor to determine whether the information satisfies a predeterminedcriteria requiring transmission of the information or a signalindicative thereof to the remote facility 108A and the communicationsportion is arranged to only transmit the obtained information when itsatisfies one of the predetermined transmission criteria.

Other communication systems will also frequently be used to connect acontainer monitored as described above with the chassis and/or thetractor and perhaps the identification of the driver or operator. Thus,information can be available on the Internet showing what tractor, whattrailer, what container and what driver is operating at a particulartime, at a particular GPS location, on a particular roadway, with whatparticular container contents. Suitable security will be provided toensure that this information is not freely available to the generalpublic. Redundancy can be provided to prevent the destruction or anyfailure of a particular site from failing the system.

This communication between the various elements of the shipping systemwhich are co-located (truck, trailer, container, container contents,driver etc.) can be connected through a wired or wireless bus such asthe CAN bus. Also, an electrical system such as disclosed in U.S. Pat.No. 5,809,437, U.S. Pat. No. 6,175,787 and U.S. Pat. No. 6,326,704 canalso be used in the invention.

Although several preferred embodiments are illustrated and describedabove, there are possible combinations using other geometries, sensors,materials and different dimensions for the components that perform thesame functions. At least one of the inventions disclosed herein is notlimited to the above embodiments and should be determined by thefollowing claims. There are also numerous additional applications inaddition to those described above. Many changes, modifications,variations and other uses and applications of the subject inventionwill, however, become apparent to those skilled in the art afterconsidering this specification and the accompanying drawings whichdisclose the preferred embodiments thereof. All such changes,modifications, variations and other uses and applications which do notdepart from the spirit and scope of the invention are deemed to becovered by the invention which is limited only by the following claims.

1. A method for obtaining information about a person when in a vehicleor the vehicle, comprising: providing the person with a portable device;arranging at least one sensor on the portable device, the at least onesensor including a microphone; receiving information from the at leastone sensor of the portable device when the portable device is situatedin the vehicle, the step of receiving information from the at least onesensor comprising receiving sounds via the microphone of the portabledevice; obtaining information about the person, the vehicle or anenvironment around the person using the at least one sensor of theportable device without manual interaction, the step of obtaininginformation comprising programming the portable device to analyze theinformation received from the at least one sensor to determine whetherthe information is indicative of an accident involving the vehicle, thestep of programming the portable device to analyze the informationcomprising programming the portable device to analyze the receivedsounds via the microphone of the portable device; and transmitting asignal based on the analysis of the received information from the atleast one sensor of the portable device when situated in the vehicle toa remote facility including a signal based on the determination ofwhether the information is indicative of an accident involving thevehicle, the step of transmitting a signal based on the analysis of thereceived information comprising transmitting to the remote facility, asignal indicative of the received sounds including the sound of anaccident involving the vehicle or the sound of deployment of an airbagof the vehicle that would deploy to protect an occupant of the vehicleduring an accident involving the vehicle.
 2. The method of claim 1,wherein the portable device is a cell phone or PDA.
 3. The method ofclaim 1, further comprising: providing the portable device with a systemto obtain GPS signals; transmitting the obtained GPS signals from theportable device to the remote facility; and determining the location ofthe portable device from the GPS signals at the remote facility.
 4. Themethod of claim 1, further comprising training the portable device torecognize the sounds of accidents such that the signal indicative of thereceiving sounds being transmitted to the remote facility is an accidentindication signal when the sound of an accident is recognized.
 5. Themethod of claim 1, wherein the at least one sensor further comprises asensor which obtains information about an environment around theportable device.
 6. The method of claim 1, wherein the at least onesensor further comprises a chemical sensor which obtains informationabout chemicals or gases in the environment around the person.
 7. Themethod of claim 1, further comprising arranging an energy harvestingsystem in connection with the portable device to generate energy topower the cell phone or PDA during movement of the vehicle.
 8. Themethod of claim 1, wherein the at least one sensor further comprises asensor arranged to obtain information about the person.
 9. The method ofclaim 1, wherein the at least one sensor further comprises a sensorselected from a group consisting of a temperature sensor, radiationsensor, optical sensor, humidity sensor, chemical sensor, biochemicalsensor, biological sensor, acceleration sensor, velocity sensors,displacement sensor, location sensor, vibration sensor, acoustic sensorand pressure sensor.
 10. The method of claim 1, further comprisinganalyzing the obtained information at the portable device to determinewhether the information satisfies a predetermined criteria requiringtransmission of the information to the remote facility and onlytransmitting the obtained information when it satisfies one of thepredetermined transmission criteria.
 11. The method of claim 1, furthercomprising: placing at least one sensor on the vehicle that isconnectable to the portable device; obtaining information from the atleast one sensor placed on the vehicle; and transmitting informationobtained from the at least one sensor placed on the vehicle from theportable device to the remote facility.
 12. The method of claim 1,further comprising: providing at least one sensor that obtainsinformation about a health state of the person when the person issituated in the vehicle; obtaining information from the at least onesensor that obtains information about a health state of the person; andtransmitting information obtained from the at least one sensor from theportable device to the remote facility.
 13. The method of claim 1,wherein the at least one sensor further comprises an inertial sensor.14. The method of claim 1, further comprising training the portabledevice to recognize the sounds of deployment of an airbag of the vehiclesuch that the signal indicative of the receiving sounds beingtransmitted to the remote facility is an airbag deployment signal whenthe sound of an airbag deployment is recognized.
 15. An arrangement formonitoring a person when in a vehicle or the vehicle, comprising: aportable device including at least one sensor and which is situated inthe vehicle when the person is in the vehicle, said at least one sensorbeing arranged to obtain information about the person, the vehicle or anenvironment around the person without manual interaction, said portabledevice including a processor which analyzes the obtained information todetermine whether the obtained information requires a transmission to aremote facility and a communications portion arranged to transmit theobtained information or a signal representative thereof when saidprocessor determines that the obtained information requires such atransmission; and a remote facility for receiving and reacting to thetransmitted information, said processor being arranged to receive theinformation obtained by said at least one sensor and analyze theinformation obtained by said at least one sensor in order to determinewhether the information is indicative of an accident involving thevehicle, and cause transmission of an accident indication signal to saidremote facility via said communications portion when it is determinedthat the information is indicative of an accident involving the vehicle,said at least one sensor comprising a microphone arranged to receivesounds when carried by the person such that the information obtained bysaid microphone is sounds in a vicinity of said portable device, saidprocessor being arranged to analyze the received sounds to recognize thesounds of accidents or sounds of deployment of an airbag of the vehiclethat would deploy to protect an occupant of the vehicle during anaccident involving the vehicle and cause transmission of a signal tosaid remote facility when the sound of an accident or airbag deploymentis recognized.
 16. The arrangement of claim 15, wherein said portabledevice is a cell phone or PDA.
 17. The arrangement of claim 15, whereinsaid portable device includes a locating system arranged to obtain GPSsignals, said communications portion being arranged to transmit theobtained GPS signals to said remote facility to enable the location ofsaid portable device to be determined from the GPS signals at saidremote facility.
 18. The arrangement of claim 15, wherein said processoris arranged to analyze-the-received sounds to recognize the sounds ofaccidents such that the signal being transmitted to said remote facilityis an accident indication signal when the sounds of an accident arerecognized.
 19. The arrangement of claim 15, wherein said at least onesensor further comprises a chemical sensor which obtains informationabout chemicals or gases in the environment around the person.
 20. Thearrangement of claim 15, wherein said at least one sensor furthercomprises a sensor arranged to obtain information about the person. 21.The arrangement of claim 15, wherein said at least one sensor furthercomprises a sensor arranged to obtain information about the environmentaround the person.
 22. The arrangement of claim 15, wherein said atleast one sensor further comprises a sensor selected from a groupconsisting of a temperature sensor, radiation sensor, optical sensor,humidity sensor, chemical sensor, biochemical sensor, biological sensor,acceleration sensor, velocity sensors, displacement sensor, locationsensor, vibration sensor, acoustic sensor and pressure sensor.
 23. Thearrangement of claim 15, wherein said processor analyzes the obtainedinformation to determine whether the information satisfies apredetermined criteria requiring transmission of the information to saidremote facility and said communications portion is arranged to onlytransmit the obtained information when it satisfies one of thepredetermined transmission criteria.
 24. The arrangement of claim 15,further comprising at least one sensor placed on the vehicle andconnectable to said portable device, said at least one sensor placed onthe vehicle being arranged to obtain information about the vehicle, saidcommunications portion being arranged to transmit information obtainedfrom said at least one sensor placed on the vehicle from said portabledevice to said remote facility.
 25. The arrangement of claim 15, furthercomprising at least one health state sensor that obtains informationabout a health state of the person when the person is situated in thevehicle, said communications portion being arranged to transmitinformation obtained from said at least one health state sensor fromsaid portable device to said remote facility.
 26. The arrangement ofclaim 15, wherein said at least one sensor further comprises an inertialsensor.
 27. The arrangement of claim 18, wherein said processor isarranged to recognize the sounds of deployment of an airbag of thevehicle such that the signal being transmitted to said remote facilityis an airbag deployment signal when the sound of an airbag deployment isrecognized.